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<meta name="author" content="David Abrahams, Jeremy Siek, Thomas Witt" />
<meta name="organization" content="Boost Consulting, Indiana University Open Systems Lab, University of Hanover Institute for Transport Railway Operation and Construction" />
<meta name="date" content="2004-11-01" />
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<h1 class="title">Iterator Adaptor</h1>
<table class="docinfo" frame="void" rules="none">
<col class="docinfo-name" />
<col class="docinfo-content" />
<tbody valign="top">
<tr><th class="docinfo-name">Author:</th>
<td>David Abrahams, Jeremy Siek, Thomas Witt</td></tr>
<tr><th class="docinfo-name">Contact:</th>
<td><a class="first reference" href="mailto:dave&#64;boost-consulting.com">dave&#64;boost-consulting.com</a>, <a class="reference" href="mailto:jsiek&#64;osl.iu.edu">jsiek&#64;osl.iu.edu</a>, <a class="last reference" href="mailto:witt&#64;ive.uni-hannover.de">witt&#64;ive.uni-hannover.de</a></td></tr>
<tr><th class="docinfo-name">Organization:</th>
<td><a class="first reference" href="http://www.boost-consulting.com">Boost Consulting</a>, Indiana University <a class="reference" href="http://www.osl.iu.edu">Open Systems
Lab</a>, University of Hanover <a class="last reference" href="http://www.ive.uni-hannover.de">Institute for Transport
Railway Operation and Construction</a></td></tr>
<tr><th class="docinfo-name">Date:</th>
<td>2004-11-01</td></tr>
<tr><th class="docinfo-name">Copyright:</th>
<td>Copyright David Abrahams, Jeremy Siek, and Thomas Witt 2003.</td></tr>
</tbody>
</table>
<div class="document" id="iterator-adaptor">
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">abstract:</th><td class="field-body"></td>
</tr>
</tbody>
</table>
<!-- Version 1.1 of this ReStructuredText document corresponds to
n1530_, the paper accepted by the LWG. -->
<!-- Copyright David Abrahams, Jeremy Siek, and Thomas Witt 2003.  -->
<p>Each specialization of the <tt class="literal"><span class="pre">iterator_adaptor</span></tt> class template is derived from
a specialization of <tt class="literal"><span class="pre">iterator_facade</span></tt>. The core interface functions
expected by <tt class="literal"><span class="pre">iterator_facade</span></tt> are implemented in terms of the
<tt class="literal"><span class="pre">iterator_adaptor</span></tt>'s <tt class="literal"><span class="pre">Base</span></tt> template parameter. A class derived
from <tt class="literal"><span class="pre">iterator_adaptor</span></tt> typically redefines some of the core
interface functions to adapt the behavior of the <tt class="literal"><span class="pre">Base</span></tt> type.
Whether the derived class models any of the standard iterator concepts
depends on the operations supported by the <tt class="literal"><span class="pre">Base</span></tt> type and which
core interface functions of <tt class="literal"><span class="pre">iterator_facade</span></tt> are redefined in the
<tt class="literal"><span class="pre">Derived</span></tt> class.</p>
<div class="contents topic" id="table-of-contents">
<p class="topic-title first"><a name="table-of-contents">Table of Contents</a></p>
<ul class="simple">
<li><a class="reference" href="#overview" id="id6" name="id6">Overview</a></li>
<li><a class="reference" href="#reference" id="id7" name="id7">Reference</a><ul>
<li><a class="reference" href="#iterator-adaptor-requirements" id="id8" name="id8"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> requirements</a></li>
<li><a class="reference" href="#iterator-adaptor-base-class-parameters" id="id9" name="id9"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> base class parameters</a></li>
<li><a class="reference" href="#iterator-adaptor-public-operations" id="id10" name="id10"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> public operations</a></li>
<li><a class="reference" href="#iterator-adaptor-protected-member-functions" id="id11" name="id11"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> protected member functions</a></li>
<li><a class="reference" href="#iterator-adaptor-private-member-functions" id="id12" name="id12"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> private member functions</a></li>
</ul>
</li>
<li><a class="reference" href="#tutorial-example" id="id13" name="id13">Tutorial Example</a></li>
</ul>
</div>
<div class="section" id="overview">
<h1><a class="toc-backref" href="#id6" name="overview">Overview</a></h1>
<!-- Version 1.2 of this ReStructuredText document corresponds to
n1530_, the paper accepted by the LWG for TR1. -->
<!-- Copyright David Abrahams, Jeremy Siek, and Thomas Witt 2003.  -->
<p>The <tt class="literal"><span class="pre">iterator_adaptor</span></tt> class template adapts some <tt class="literal"><span class="pre">Base</span></tt> <a class="footnote-reference" href="#base" id="id1" name="id1"><sup>1</sup></a>
type to create a new iterator.  Instantiations of <tt class="literal"><span class="pre">iterator_adaptor</span></tt>
are derived from a corresponding instantiation of <tt class="literal"><span class="pre">iterator_facade</span></tt>
and implement the core behaviors in terms of the <tt class="literal"><span class="pre">Base</span></tt> type. In
essence, <tt class="literal"><span class="pre">iterator_adaptor</span></tt> merely forwards all operations to an
instance of the <tt class="literal"><span class="pre">Base</span></tt> type, which it stores as a member.</p>
<table class="footnote" frame="void" id="base" rules="none">
<colgroup><col class="label" /><col /></colgroup>
<tbody valign="top">
<tr><td class="label"><a name="base">[1]</a></td><td><em>(<a class="fn-backref" href="#id1">1</a>, <a class="fn-backref" href="#id3">2</a>)</em> The term &quot;Base&quot; here does not refer to a base class and is
not meant to imply the use of derivation. We have followed the lead
of the standard library, which provides a base() function to access
the underlying iterator object of a <tt class="literal"><span class="pre">reverse_iterator</span></tt> adaptor.</td></tr>
</tbody>
</table>
<p>The user of <tt class="literal"><span class="pre">iterator_adaptor</span></tt> creates a class derived from an
instantiation of <tt class="literal"><span class="pre">iterator_adaptor</span></tt> and then selectively
redefines some of the core member functions described in the
<tt class="literal"><span class="pre">iterator_facade</span></tt> core requirements table. The <tt class="literal"><span class="pre">Base</span></tt> type need
not meet the full requirements for an iterator; it need only
support the operations used by the core interface functions of
<tt class="literal"><span class="pre">iterator_adaptor</span></tt> that have not been redefined in the user's
derived class.</p>
<p>Several of the template parameters of <tt class="literal"><span class="pre">iterator_adaptor</span></tt> default
to <tt class="literal"><span class="pre">use_default</span></tt>. This allows the
user to make use of a default parameter even when she wants to
specify a parameter later in the parameter list.  Also, the
defaults for the corresponding associated types are somewhat
complicated, so metaprogramming is required to compute them, and
<tt class="literal"><span class="pre">use_default</span></tt> can help to simplify the implementation.  Finally,
the identity of the <tt class="literal"><span class="pre">use_default</span></tt> type is not left unspecified
because specification helps to highlight that the <tt class="literal"><span class="pre">Reference</span></tt>
template parameter may not always be identical to the iterator's
<tt class="literal"><span class="pre">reference</span></tt> type, and will keep users from making mistakes based on
that assumption.</p>
</div>
<div class="section" id="reference">
<h1><a class="toc-backref" href="#id7" name="reference">Reference</a></h1>
<!-- Version 1.4 of this ReStructuredText document corresponds to
n1530_, the paper accepted by the LWG for TR1. -->
<!-- Copyright David Abrahams, Jeremy Siek, and Thomas Witt 2003.  -->
<pre class="literal-block">
template &lt;
    class Derived
  , class Base
  , class Value               = use_default
  , class CategoryOrTraversal = use_default
  , class Reference           = use_default
  , class Difference = use_default
&gt;
class iterator_adaptor 
  : public iterator_facade&lt;Derived, <em>V'</em>, <em>C'</em>, <em>R'</em>, <em>D'</em>&gt; // see <a class="reference" href="#base-parameters">details</a>
{
    friend class iterator_core_access;
 public:
    iterator_adaptor();
    explicit iterator_adaptor(Base iter);
    Base const&amp; base() const;
 protected:
    typedef iterator_adaptor iterator_adaptor_;
    Base const&amp; base_reference() const;
    Base&amp; base_reference();
 private: // Core iterator interface for iterator_facade.  
    typename iterator_adaptor::reference dereference() const;

    template &lt;
    class OtherDerived, class OtherIterator, class V, class C, class R, class D
    &gt;   
    bool equal(iterator_adaptor&lt;OtherDerived, OtherIterator, V, C, R, D&gt; const&amp; x) const;

    void advance(typename iterator_adaptor::difference_type n);
    void increment();
    void decrement();

    template &lt;
        class OtherDerived, class OtherIterator, class V, class C, class R, class D
    &gt;   
    typename iterator_adaptor::difference_type distance_to(
        iterator_adaptor&lt;OtherDerived, OtherIterator, V, C, R, D&gt; const&amp; y) const;

 private:
    Base m_iterator; // exposition only
};
</pre>
<a class="target" id="requirements" name="requirements"></a><div class="section" id="iterator-adaptor-requirements">
<h2><a class="toc-backref" href="#id8" name="iterator-adaptor-requirements"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> requirements</a></h2>
<p><tt class="literal"><span class="pre">static_cast&lt;Derived*&gt;(iterator_adaptor*)</span></tt> shall be well-formed.
The <tt class="literal"><span class="pre">Base</span></tt> argument shall be Assignable and Copy Constructible.</p>
<a class="target" id="base-parameters" name="base-parameters"></a></div>
<div class="section" id="iterator-adaptor-base-class-parameters">
<h2><a class="toc-backref" href="#id9" name="iterator-adaptor-base-class-parameters"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> base class parameters</a></h2>
<p>The <em>V'</em>, <em>C'</em>, <em>R'</em>, and <em>D'</em> parameters of the <tt class="literal"><span class="pre">iterator_facade</span></tt>
used as a base class in the summary of <tt class="literal"><span class="pre">iterator_adaptor</span></tt>
above are defined as follows:</p>
<pre class="literal-block">
<em>V'</em> = if (Value is use_default)
          return iterator_traits&lt;Base&gt;::value_type
      else
          return Value

<em>C'</em> = if (CategoryOrTraversal is use_default)
          return iterator_traversal&lt;Base&gt;::type
      else
          return CategoryOrTraversal

<em>R'</em> = if (Reference is use_default)
          if (Value is use_default)
              return iterator_traits&lt;Base&gt;::reference
          else
              return Value&amp;
      else
          return Reference

<em>D'</em> = if (Difference is use_default)
          return iterator_traits&lt;Base&gt;::difference_type
      else
          return Difference
</pre>
<!-- ``iterator_adaptor`` models
- - - - - - - - - - - - - - - - - - - - - - - - - - -

In order for ``Derived`` to model the iterator concepts corresponding
to ``iterator_traits<Derived>::iterator_category``, the expressions
involving ``m_iterator`` in the specifications of those private member
functions of ``iterator_adaptor`` that may be called by
``iterator_facade<Derived, V, C, R, D>`` in evaluating any valid
expression involving ``Derived`` in those concepts' requirements. -->
<!-- The above is confusing and needs a rewrite. -JGS -->
<!-- That's why it's removed.  We're embracing inheritance, remember? -->
</div>
<div class="section" id="iterator-adaptor-public-operations">
<h2><a class="toc-backref" href="#id10" name="iterator-adaptor-public-operations"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> public operations</a></h2>
<p><tt class="literal"><span class="pre">iterator_adaptor();</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Requires:</th><td class="field-body">The <tt class="literal"><span class="pre">Base</span></tt> type must be Default Constructible.</td>
</tr>
<tr class="field"><th class="field-name">Returns:</th><td class="field-body">An instance of <tt class="literal"><span class="pre">iterator_adaptor</span></tt> with 
<tt class="literal"><span class="pre">m_iterator</span></tt> default constructed.</td>
</tr>
</tbody>
</table>
<p><tt class="literal"><span class="pre">explicit</span> <span class="pre">iterator_adaptor(Base</span> <span class="pre">iter);</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body">An instance of <tt class="literal"><span class="pre">iterator_adaptor</span></tt> with
<tt class="literal"><span class="pre">m_iterator</span></tt> copy constructed from <tt class="literal"><span class="pre">iter</span></tt>.</td>
</tr>
</tbody>
</table>
<p><tt class="literal"><span class="pre">Base</span> <span class="pre">const&amp;</span> <span class="pre">base()</span> <span class="pre">const;</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body"><tt class="literal"><span class="pre">m_iterator</span></tt></td>
</tr>
</tbody>
</table>
</div>
<div class="section" id="iterator-adaptor-protected-member-functions">
<h2><a class="toc-backref" href="#id11" name="iterator-adaptor-protected-member-functions"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> protected member functions</a></h2>
<p><tt class="literal"><span class="pre">Base</span> <span class="pre">const&amp;</span> <span class="pre">base_reference()</span> <span class="pre">const;</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body">A const reference to <tt class="literal"><span class="pre">m_iterator</span></tt>.</td>
</tr>
</tbody>
</table>
<p><tt class="literal"><span class="pre">Base&amp;</span> <span class="pre">base_reference();</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body">A non-const reference to <tt class="literal"><span class="pre">m_iterator</span></tt>.</td>
</tr>
</tbody>
</table>
</div>
<div class="section" id="iterator-adaptor-private-member-functions">
<h2><a class="toc-backref" href="#id12" name="iterator-adaptor-private-member-functions"><tt class="literal"><span class="pre">iterator_adaptor</span></tt> private member functions</a></h2>
<p><tt class="literal"><span class="pre">typename</span> <span class="pre">iterator_adaptor::reference</span> <span class="pre">dereference()</span> <span class="pre">const;</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body"><tt class="literal"><span class="pre">*m_iterator</span></tt></td>
</tr>
</tbody>
</table>
<pre class="literal-block">
template &lt;
class OtherDerived, class OtherIterator, class V, class C, class R, class D
&gt;   
bool equal(iterator_adaptor&lt;OtherDerived, OtherIterator, V, C, R, D&gt; const&amp; x) const;
</pre>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body"><tt class="literal"><span class="pre">m_iterator</span> <span class="pre">==</span> <span class="pre">x.base()</span></tt></td>
</tr>
</tbody>
</table>
<p><tt class="literal"><span class="pre">void</span> <span class="pre">advance(typename</span> <span class="pre">iterator_adaptor::difference_type</span> <span class="pre">n);</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Effects:</th><td class="field-body"><tt class="literal"><span class="pre">m_iterator</span> <span class="pre">+=</span> <span class="pre">n;</span></tt></td>
</tr>
</tbody>
</table>
<p><tt class="literal"><span class="pre">void</span> <span class="pre">increment();</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Effects:</th><td class="field-body"><tt class="literal"><span class="pre">++m_iterator;</span></tt></td>
</tr>
</tbody>
</table>
<p><tt class="literal"><span class="pre">void</span> <span class="pre">decrement();</span></tt></p>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Effects:</th><td class="field-body"><tt class="literal"><span class="pre">--m_iterator;</span></tt></td>
</tr>
</tbody>
</table>
<pre class="literal-block">
template &lt;
    class OtherDerived, class OtherIterator, class V, class C, class R, class D
&gt;   
typename iterator_adaptor::difference_type distance_to(
    iterator_adaptor&lt;OtherDerived, OtherIterator, V, C, R, D&gt; const&amp; y) const;
</pre>
<table class="field-list" frame="void" rules="none">
<col class="field-name" />
<col class="field-body" />
<tbody valign="top">
<tr class="field"><th class="field-name">Returns:</th><td class="field-body"><tt class="literal"><span class="pre">y.base()</span> <span class="pre">-</span> <span class="pre">m_iterator</span></tt></td>
</tr>
</tbody>
</table>
</div>
</div>
<div class="section" id="tutorial-example">
<h1><a class="toc-backref" href="#id13" name="tutorial-example">Tutorial Example</a></h1>
<!-- Copyright David Abrahams 2004. Use, modification and distribution is -->
<!-- subject to the Boost Software License, Version 1.0. (See accompanying -->
<!-- file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) -->
<p>In this section we'll further refine the <tt class="literal"><span class="pre">node_iter</span></tt> class
template we developed in the <a class="reference" href="iterator_facade.html#tutorial-example"><tt class="literal"><span class="pre">iterator_facade</span></tt> tutorial</a>.  If you haven't already
read that material, you should go back now and check it out because
we're going to pick up right where it left off.</p>
<div class="sidebar">
<p class="sidebar-title first"><tt class="literal"><span class="pre">node_base*</span></tt> really <em>is</em> an iterator</p>
<p>It's not really a very interesting iterator, since <tt class="literal"><span class="pre">node_base</span></tt>
is an abstract class: a pointer to a <tt class="literal"><span class="pre">node_base</span></tt> just points
at some base subobject of an instance of some other class, and
incrementing a <tt class="literal"><span class="pre">node_base*</span></tt> moves it past this base subobject
to who-knows-where?  The most we can do with that incremented
position is to compare another <tt class="literal"><span class="pre">node_base*</span></tt> to it.  In other
words, the original iterator traverses a one-element array.</p>
</div>
<p>You probably didn't think of it this way, but the <tt class="literal"><span class="pre">node_base*</span></tt>
object that underlies <tt class="literal"><span class="pre">node_iterator</span></tt> is itself an iterator,
just like all other pointers.  If we examine that pointer closely
from an iterator perspective, we can see that it has much in common
with the <tt class="literal"><span class="pre">node_iterator</span></tt> we're building.  First, they share most
of the same associated types (<tt class="literal"><span class="pre">value_type</span></tt>, <tt class="literal"><span class="pre">reference</span></tt>,
<tt class="literal"><span class="pre">pointer</span></tt>, and <tt class="literal"><span class="pre">difference_type</span></tt>).  Second, even some of the
core functionality is the same: <tt class="literal"><span class="pre">operator*</span></tt> and <tt class="literal"><span class="pre">operator==</span></tt> on
the <tt class="literal"><span class="pre">node_iterator</span></tt> return the result of invoking the same
operations on the underlying pointer, via the <tt class="literal"><span class="pre">node_iterator</span></tt>'s
<a class="reference" href="iterator_facade.html#implementing-the-core-operations"><tt class="literal"><span class="pre">dereference</span></tt> and <tt class="literal"><span class="pre">equal</span></tt> member functions</a>).  The only real behavioral difference
between <tt class="literal"><span class="pre">node_base*</span></tt> and <tt class="literal"><span class="pre">node_iterator</span></tt> can be observed when
they are incremented: <tt class="literal"><span class="pre">node_iterator</span></tt> follows the
<tt class="literal"><span class="pre">m_next</span></tt> pointer, while <tt class="literal"><span class="pre">node_base*</span></tt> just applies an address offset.</p>
<p>It turns out that the pattern of building an iterator on another
iterator-like type (the <tt class="literal"><span class="pre">Base</span></tt> <a class="footnote-reference" href="#base" id="id3" name="id3"><sup>1</sup></a> type) while modifying
just a few aspects of the underlying type's behavior is an
extremely common one, and it's the pattern addressed by
<tt class="literal"><span class="pre">iterator_adaptor</span></tt>.  Using <tt class="literal"><span class="pre">iterator_adaptor</span></tt> is very much like
using <tt class="literal"><span class="pre">iterator_facade</span></tt>, but because iterator_adaptor tries to
mimic as much of the <tt class="literal"><span class="pre">Base</span></tt> type's behavior as possible, we
neither have to supply a <tt class="literal"><span class="pre">Value</span></tt> argument, nor implement any core
behaviors other than <tt class="literal"><span class="pre">increment</span></tt>.  The implementation of
<tt class="literal"><span class="pre">node_iter</span></tt> is thus reduced to:</p>
<pre class="literal-block">
template &lt;class Value&gt;
class node_iter
  : public boost::iterator_adaptor&lt;
        node_iter&lt;Value&gt;                // Derived
      , Value*                          // Base
      , boost::use_default              // Value
      , boost::forward_traversal_tag    // CategoryOrTraversal
    &gt;
{
 private:
    struct enabler {};  // a private type avoids misuse

 public:
    node_iter()
      : node_iter::iterator_adaptor_(0) {}

    explicit node_iter(Value* p)
      : node_iter::iterator_adaptor_(p) {}

    template &lt;class OtherValue&gt;
    node_iter(
        node_iter&lt;OtherValue&gt; const&amp; other
      , typename boost::enable_if&lt;
            boost::is_convertible&lt;OtherValue*,Value*&gt;
          , enabler
        &gt;::type = enabler()
    )
      : node_iter::iterator_adaptor_(other.base()) {}

 private:
    friend class boost::iterator_core_access;
    void increment() { this-&gt;base_reference() = this-&gt;base()-&gt;next(); }
};
</pre>
<p>Note the use of <tt class="literal"><span class="pre">node_iter::iterator_adaptor_</span></tt> here: because
<tt class="literal"><span class="pre">iterator_adaptor</span></tt> defines a nested <tt class="literal"><span class="pre">iterator_adaptor_</span></tt> type
that refers to itself, that gives us a convenient way to refer to
the complicated base class type of <tt class="literal"><span class="pre">node_iter&lt;Value&gt;</span></tt>. [Note:
this technique is known not to work with Borland C++ 5.6.4 and
Metrowerks CodeWarrior versions prior to 9.0]</p>
<p>You can see an example program that exercises this version of the
node iterators <a class="reference" href="../example/node_iterator3.cpp">here</a>.</p>
<p>In the case of <tt class="literal"><span class="pre">node_iter</span></tt>, it's not very compelling to pass
<tt class="literal"><span class="pre">boost::use_default</span></tt> as <tt class="literal"><span class="pre">iterator_adaptor</span></tt>'s <tt class="literal"><span class="pre">Value</span></tt>
argument; we could have just passed <tt class="literal"><span class="pre">node_iter</span></tt>'s <tt class="literal"><span class="pre">Value</span></tt>
along to <tt class="literal"><span class="pre">iterator_adaptor</span></tt>, and that'd even be shorter!  Most
iterator class templates built with <tt class="literal"><span class="pre">iterator_adaptor</span></tt> are
parameterized on another iterator type, rather than on its
<tt class="literal"><span class="pre">value_type</span></tt>.  For example, <tt class="literal"><span class="pre">boost::reverse_iterator</span></tt> takes an
iterator type argument and reverses its direction of traversal,
since the original iterator and the reversed one have all the same
associated types, <tt class="literal"><span class="pre">iterator_adaptor</span></tt>'s delegation of default
types to its <tt class="literal"><span class="pre">Base</span></tt> saves the implementor of
<tt class="literal"><span class="pre">boost::reverse_iterator</span></tt> from writing:</p>
<pre class="literal-block">
std::iterator_traits&lt;Iterator&gt;::<em>some-associated-type</em>
</pre>
<p>at least four times.</p>
<p>We urge you to review the documentation and implementations of
<a class="reference" href="reverse_iterator.html"><tt class="literal"><span class="pre">reverse_iterator</span></tt></a> and the other Boost <a class="reference" href="index.html#specialized-adaptors">specialized iterator
adaptors</a> to get an idea of the sorts of things you can do with
<tt class="literal"><span class="pre">iterator_adaptor</span></tt>.  In particular, have a look at
<a class="reference" href="transform_iterator.html"><tt class="literal"><span class="pre">transform_iterator</span></tt></a>, which is perhaps the most straightforward
adaptor, and also <a class="reference" href="counting_iterator.html"><tt class="literal"><span class="pre">counting_iterator</span></tt></a>, which demonstrates that
<tt class="literal"><span class="pre">iterator_adaptor</span></tt>'s <tt class="literal"><span class="pre">Base</span></tt> type needn't be an iterator.</p>
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