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<div class="section">

<div class="titlepage"><div><div><h2 class="title" style="clear: both">

<a name="python.object"></a>Object Interface</h2></div></div></div>

<div class="toc"><dl>

<dt><span class="section"><a href="object.html#python.basic_interface">Basic Interface</a></span></dt>

<dt><span class="section"><a href="object.html#python.derived_object_types">Derived Object types</a></span></dt>

<dt><span class="section"><a href="object.html#python.extracting_c___objects">Extracting C++ objects</a></span></dt>

<dt><span class="section"><a href="object.html#python.enums">Enums</a></span></dt>

<dt><span class="section"><a href="object.html#python.creating_python_object">Creating <code class="computeroutput"><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">object</span></code> from <code class="computeroutput"><span class="identifier">PyObject</span><span class="special">*</span></code></a></span></dt>

Python is dynamically typed, unlike C++ which is statically typed. Python variables

may hold an integer, a float, list, dict, tuple, str, long etc., among other

things. In the viewpoint of Boost.Python and C++, these Pythonic variables

are just instances of class <code class="literal">object</code>. We will see in this

chapter how to deal with Python objects.

</p>

As mentioned, one of the goals of Boost.Python is to provide a bidirectional

mapping between C++ and Python while maintaining the Python feel. Boost.Python

C++ <code class="literal">object</code>s are as close as possible to Python. This should

minimize the learning curve significantly.

</p>

<span class="inlinemediaobject"><img src="../images/python.png" alt="python"></span>

</p>

<div class="section">

<div class="titlepage"><div><div><h3 class="title">

<a name="python.basic_interface"></a>Basic Interface</h3></div></div></div>

Class <code class="literal">object</code> wraps <code class="literal">PyObject*</code>. All the

intricacies of dealing with <code class="literal">PyObject</code>s such as managing

reference counting are handled by the <code class="literal">object</code> class. C++

object interoperability is seamless. Boost.Python C++ <code class="literal">object</code>s

can in fact be explicitly constructed from any C++ object.

</p>

To illustrate, this Python code snippet:

</p>

<pre class="programlisting"><span class="keyword">def</span> <span class="identifier">f</span><span class="special">(</span><span class="identifier">x</span><span class="special">,</span> <span class="identifier">y</span><span class="special">):</span>

<span class="keyword">if</span> <span class="special">(</span><span class="identifier">y</span> <span class="special">==</span> <span class="string">'foo'</span><span class="special">):</span>

<span class="identifier">x</span><span class="special">[</span><span class="number">3</span><span class="special">:</span><span class="number">7</span><span class="special">]</span> <span class="special">=</span> <span class="string">'bar'</span>

<span class="keyword">else</span><span class="special">:</span>

<span class="identifier">x</span><span class="special">.</span><span class="identifier">items</span> <span class="special">+=</span> <span class="identifier">y</span><span class="special">(</span><span class="number">3</span><span class="special">,</span> <span class="identifier">x</span><span class="special">)</span>

<span class="keyword">return</span> <span class="identifier">x</span>

<span class="keyword">def</span> <span class="identifier">getfunc</span><span class="special">():</span>

<span class="keyword">return</span> <span class="identifier">f</span><span class="special">;</span>

Can be rewritten in C++ using Boost.Python facilities this way:

</p>

<pre class="programlisting"><span class="identifier">object</span> <span class="identifier">f</span><span class="special">(</span><span class="identifier">object</span> <span class="identifier">x</span><span class="special">,</span> <span class="identifier">object</span> <span class="identifier">y</span><span class="special">)</span> <span class="special">{</span>

<span class="keyword">if</span> <span class="special">(</span><span class="identifier">y</span> <span class="special">==</span> <span class="string">"foo"</span><span class="special">)</span>

<span class="identifier">x</span><span class="special">.</span><span class="identifier">slice</span><span class="special">(</span><span class="number">3</span><span class="special">,</span><span class="number">7</span><span class="special">)</span> <span class="special">=</span> <span class="string">"bar"</span><span class="special">;</span>

<span class="keyword">else</span>

<span class="identifier">x</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"items"</span><span class="special">)</span> <span class="special">+=</span> <span class="identifier">y</span><span class="special">(</span><span class="number">3</span><span class="special">,</span> <span class="identifier">x</span><span class="special">);</span>

<span class="keyword">return</span> <span class="identifier">x</span><span class="special">;</span>

<span class="special">}</span>

<span class="identifier">object</span> <span class="identifier">getfunc</span><span class="special">()</span> <span class="special">{</span>

<span class="keyword">return</span> <span class="identifier">object</span><span class="special">(</span><span class="identifier">f</span><span class="special">);</span>

<span class="special">}</span>

Apart from cosmetic differences due to the fact that we are writing the code

in C++, the look and feel should be immediately apparent to the Python coder.

</p>

<div class="section">

<div class="titlepage"><div><div><h3 class="title">

<a name="python.derived_object_types"></a>Derived Object types</h3></div></div></div>

Boost.Python comes with a set of derived <code class="literal">object</code> types

corresponding to that of Python's:

</p>

<div class="itemizedlist"><ul class="itemizedlist" type="disc">

<li class="listitem">

list

</li>

<li class="listitem">

dict

</li>

<li class="listitem">

tuple

</li>

<li class="listitem">

str

</li>

<li class="listitem">

long_

</li>

<li class="listitem">

enum

</li>

These derived <code class="literal">object</code> types act like real Python types.

For instance:

</p>

<pre class="programlisting"><span class="identifier">str</span><span class="special">(</span><span class="number">1</span><span class="special">)</span> <span class="special">==&gt;</span> <span class="string">"1"</span>

Wherever appropriate, a particular derived <code class="literal">object</code> has

corresponding Python type's methods. For instance, <code class="literal">dict</code>

has a <code class="literal">keys()</code> method:

</p>

<pre class="programlisting"><span class="identifier">d</span><span class="special">.</span><span class="identifier">keys</span><span class="special">()</span>

<code class="literal">make_tuple</code> is provided for declaring <span class="emphasis"><em>tuple literals</em></span>.

Example:

</p>

<pre class="programlisting"><span class="identifier">make_tuple</span><span class="special">(</span><span class="number">123</span><span class="special">,</span> <span class="char">'D'</span><span class="special">,</span> <span class="string">"Hello, World"</span><span class="special">,</span> <span class="number">0.0</span><span class="special">);</span>

In C++, when Boost.Python <code class="literal">object</code>s are used as arguments

to functions, subtype matching is required. For example, when a function

<code class="literal">f</code>, as declared below, is wrapped, it will only accept

instances of Python's <code class="literal">str</code> type and subtypes.

</p>

<pre class="programlisting"><span class="keyword">void</span> <span class="identifier">f</span><span class="special">(</span><span class="identifier">str</span> <span class="identifier">name</span><span class="special">)</span>

<span class="special">{</span>

<span class="identifier">object</span> <span class="identifier">n2</span> <span class="special">=</span> <span class="identifier">name</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"upper"</span><span class="special">)();</span> <span class="comment">// NAME = name.upper()</span>

<span class="identifier">str</span> <span class="identifier">NAME</span> <span class="special">=</span> <span class="identifier">name</span><span class="special">.</span><span class="identifier">upper</span><span class="special">();</span> <span class="comment">// better</span>

<span class="identifier">object</span> <span class="identifier">msg</span> <span class="special">=</span> <span class="string">"%s is bigger than %s"</span> <span class="special">%</span> <span class="identifier">make_tuple</span><span class="special">(</span><span class="identifier">NAME</span><span class="special">,</span><span class="identifier">name</span><span class="special">);</span>

<span class="special">}</span>

In finer detail:

</p>

<pre class="programlisting"><span class="identifier">str</span> <span class="identifier">NAME</span> <span class="special">=</span> <span class="identifier">name</span><span class="special">.</span><span class="identifier">upper</span><span class="special">();</span>

Illustrates that we provide versions of the str type's methods as C++ member

functions.

</p>

<pre class="programlisting"><span class="identifier">object</span> <span class="identifier">msg</span> <span class="special">=</span> <span class="string">"%s is bigger than %s"</span> <span class="special">%</span> <span class="identifier">make_tuple</span><span class="special">(</span><span class="identifier">NAME</span><span class="special">,</span><span class="identifier">name</span><span class="special">);</span>

Demonstrates that you can write the C++ equivalent of <code class="literal">"format"

% x,y,z</code> in Python, which is useful since there's no easy way to

do that in std C++.

</p>

<div class="sidebar">

<div class="titlepage"></div>

<span class="inlinemediaobject"><img src="../images/alert.png" alt="alert"></span> <span class="bold"><strong>Beware</strong></span> the common pitfall

of forgetting that the constructors of most of Python's mutable types make

copies, just as in Python.

</p>

Python:

</p>

<pre class="programlisting"><span class="special">&gt;&gt;&gt;</span> <span class="identifier">d</span> <span class="special">=</span> <span class="identifier">dict</span><span class="special">(</span><span class="identifier">x</span><span class="special">.</span><span class="identifier">__dict__</span><span class="special">)</span> <span class="comment"># copies x.__dict__</span>

<span class="special">&gt;&gt;&gt;</span> <span class="identifier">d</span><span class="special">[</span><span class="string">'whatever'</span><span class="special">]</span> <span class="special">=</span> <span class="number">3</span> <span class="comment"># modifies the copy</span>

C++:

</p>

<pre class="programlisting"><span class="identifier">dict</span> <span class="identifier">d</span><span class="special">(</span><span class="identifier">x</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"__dict__"</span><span class="special">));</span> <span class="comment">// copies x.__dict__</span>

<span class="identifier">d</span><span class="special">[</span><span class="char">'whatever'</span><span class="special">]</span> <span class="special">=</span> <span class="number">3</span><span class="special">;</span> <span class="comment">// modifies the copy</span>

<a name="derived_object_types.class__lt_t_gt__as_objects"></a>

class_&lt;T&gt; as objects

</h3>

Due to the dynamic nature of Boost.Python objects, any <code class="literal">class_&lt;T&gt;</code>

may also be one of these types! The following code snippet wraps the class

(type) object.

</p>

We can use this to create wrapped instances. Example:

</p>

<pre class="programlisting"><span class="identifier">object</span> <span class="identifier">vec345</span> <span class="special">=</span> <span class="special">(</span>

<span class="identifier">class_</span><span class="special">&lt;</span><span class="identifier">Vec2</span><span class="special">&gt;(</span><span class="string">"Vec2"</span><span class="special">,</span> <span class="identifier">init</span><span class="special">&lt;</span><span class="keyword">double</span><span class="special">,</span> <span class="keyword">double</span><span class="special">&gt;())</span>

<span class="special">.</span><span class="identifier">def_readonly</span><span class="special">(</span><span class="string">"length"</span><span class="special">,</span> <span class="special">&amp;</span><span class="identifier">Point</span><span class="special">::</span><span class="identifier">length</span><span class="special">)</span>

<span class="special">.</span><span class="identifier">def_readonly</span><span class="special">(</span><span class="string">"angle"</span><span class="special">,</span> <span class="special">&amp;</span><span class="identifier">Point</span><span class="special">::</span><span class="identifier">angle</span><span class="special">)</span>

<span class="special">)(</span><span class="number">3.0</span><span class="special">,</span> <span class="number">4.0</span><span class="special">);</span>

<span class="identifier">assert</span><span class="special">(</span><span class="identifier">vec345</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"length"</span><span class="special">)</span> <span class="special">==</span> <span class="number">5.0</span><span class="special">);</span>

<div class="section">

<div class="titlepage"><div><div><h3 class="title">

<a name="python.extracting_c___objects"></a>Extracting C++ objects</h3></div></div></div>

At some point, we will need to get C++ values out of object instances. This

can be achieved with the <code class="literal">extract&lt;T&gt;</code> function. Consider

the following:

</p>

<pre class="programlisting"><span class="keyword">double</span> <span class="identifier">x</span> <span class="special">=</span> <span class="identifier">o</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"length"</span><span class="special">);</span> <span class="comment">// compile error</span>

In the code above, we got a compiler error because Boost.Python <code class="literal">object</code>

can't be implicitly converted to <code class="literal">double</code>s. Instead, what

we wanted to do above can be achieved by writing:

</p>

<pre class="programlisting"><span class="keyword">double</span> <span class="identifier">l</span> <span class="special">=</span> <span class="identifier">extract</span><span class="special">&lt;</span><span class="keyword">double</span><span class="special">&gt;(</span><span class="identifier">o</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"length"</span><span class="special">));</span>

<span class="identifier">Vec2</span><span class="special">&amp;</span> <span class="identifier">v</span> <span class="special">=</span> <span class="identifier">extract</span><span class="special">&lt;</span><span class="identifier">Vec2</span><span class="special">&amp;&gt;(</span><span class="identifier">o</span><span class="special">);</span>

<span class="identifier">assert</span><span class="special">(</span><span class="identifier">l</span> <span class="special">==</span> <span class="identifier">v</span><span class="special">.</span><span class="identifier">length</span><span class="special">());</span>

The first line attempts to extract the "length" attribute of the

Boost.Python <code class="literal">object</code>. The second line attempts to <span class="emphasis"><em>extract</em></span>

the <code class="literal">Vec2</code> object from held by the Boost.Python <code class="literal">object</code>.

</p>

Take note that we said "attempt to" above. What if the Boost.Python

<code class="literal">object</code> does not really hold a <code class="literal">Vec2</code>

type? This is certainly a possibility considering the dynamic nature of Python

<code class="literal">object</code>s. To be on the safe side, if the C++ type can't

be extracted, an appropriate exception is thrown. To avoid an exception,

we need to test for extractibility:

</p>

<pre class="programlisting"><span class="identifier">extract</span><span class="special">&lt;</span><span class="identifier">Vec2</span><span class="special">&amp;&gt;</span> <span class="identifier">x</span><span class="special">(</span><span class="identifier">o</span><span class="special">);</span>

<span class="keyword">if</span> <span class="special">(</span><span class="identifier">x</span><span class="special">.</span><span class="identifier">check</span><span class="special">())</span> <span class="special">{</span>

<span class="identifier">Vec2</span><span class="special">&amp;</span> <span class="identifier">v</span> <span class="special">=</span> <span class="identifier">x</span><span class="special">();</span> <span class="special">...</span>

<span class="inlinemediaobject"><img src="../images/tip.png" alt="tip"></span> The astute reader might have noticed that the <code class="literal">extract&lt;T&gt;</code>

facility in fact solves the mutable copying problem:

</p>

<pre class="programlisting"><span class="identifier">dict</span> <span class="identifier">d</span> <span class="special">=</span> <span class="identifier">extract</span><span class="special">&lt;</span><span class="identifier">dict</span><span class="special">&gt;(</span><span class="identifier">x</span><span class="special">.</span><span class="identifier">attr</span><span class="special">(</span><span class="string">"__dict__"</span><span class="special">));</span>

<span class="identifier">d</span><span class="special">[</span><span class="string">"whatever"</span><span class="special">]</span> <span class="special">=</span> <span class="number">3</span><span class="special">;</span> <span class="comment">// modifies x.__dict__ !</span>

<div class="section">

<div class="titlepage"><div><div><h3 class="title">

<a name="python.enums"></a>Enums</h3></div></div></div>

Boost.Python has a nifty facility to capture and wrap C++ enums. While Python

has no <code class="literal">enum</code> type, we'll often want to expose our C++ enums

to Python as an <code class="literal">int</code>. Boost.Python's enum facility makes

this easy while taking care of the proper conversions from Python's dynamic

typing to C++'s strong static typing (in C++, ints cannot be implicitly converted

to enums). To illustrate, given a C++ enum:

</p>

<pre class="programlisting"><span class="keyword">enum</span> <span class="identifier">choice</span> <span class="special">{</span> <span class="identifier">red</span><span class="special">,</span> <span class="identifier">blue</span> <span class="special">};</span>

the construct:

</p>

<pre class="programlisting"><span class="identifier">enum_</span><span class="special">&lt;</span><span class="identifier">choice</span><span class="special">&gt;(</span><span class="string">"choice"</span><span class="special">)</span>

<span class="special">.</span><span class="identifier">value</span><span class="special">(</span><span class="string">"red"</span><span class="special">,</span> <span class="identifier">red</span><span class="special">)</span>

<span class="special">.</span><span class="identifier">value</span><span class="special">(</span><span class="string">"blue"</span><span class="special">,</span> <span class="identifier">blue</span><span class="special">)</span>

<span class="special">;</span>

can be used to expose to Python. The new enum type is created in the current

<code class="literal">scope()</code>, which is usually the current module. The snippet

above creates a Python class derived from Python's <code class="literal">int</code>

type which is associated with the C++ type passed as its first parameter.

</p>

<div class="note"><table border="0" summary="Note">

<td rowspan="2" align="center" valign="top" width="25"><img alt="[Note]" src="../../../../../../../doc/src/images/note.png"></td>

<th align="left">Note</th>

<tr><td align="left" valign="top">

<span class="bold"><strong>what is a scope?</strong></span>

</p>

The scope is a class that has an associated global Python object which

controls the Python namespace in which new extension classes and wrapped

functions will be defined as attributes. Details can be found <a href="../../../../v2/scope.html" target="_top">here</a>.

</p>

You can access those values in Python as

</p>

<pre class="programlisting"><span class="special">&gt;&gt;&gt;</span> <span class="identifier">my_module</span><span class="special">.</span><span class="identifier">choice</span><span class="special">.</span><span class="identifier">red</span>

<span class="identifier">my_module</span><span class="special">.</span><span class="identifier">choice</span><span class="special">.</span><span class="identifier">red</span>

where my_module is the module where the enum is declared. You can also create

a new scope around a class:

</p>

<pre class="programlisting"><span class="identifier">scope</span> <span class="identifier">in_X</span> <span class="special">=</span> <span class="identifier">class_</span><span class="special">&lt;</span><span class="identifier">X</span><span class="special">&gt;(</span><span class="string">"X"</span><span class="special">)</span>

<span class="special">.</span><span class="identifier">def</span><span class="special">(</span> <span class="special">...</span> <span class="special">)</span>

<span class="special">.</span><span class="identifier">def</span><span class="special">(</span> <span class="special">...</span> <span class="special">)</span>

<span class="special">;</span>

<span class="comment">// Expose X::nested as X.nested</span>

<span class="identifier">enum_</span><span class="special">&lt;</span><span class="identifier">X</span><span class="special">::</span><span class="identifier">nested</span><span class="special">&gt;(</span><span class="string">"nested"</span><span class="special">)</span>

<span class="special">.</span><span class="identifier">value</span><span class="special">(</span><span class="string">"red"</span><span class="special">,</span> <span class="identifier">red</span><span class="special">)</span>

<span class="special">.</span><span class="identifier">value</span><span class="special">(</span><span class="string">"blue"</span><span class="special">,</span> <span class="identifier">blue</span><span class="special">)</span>

<span class="special">;</span>

<div class="section">

<div class="titlepage"><div><div><h3 class="title">

<a name="python.creating_python_object"></a>Creating <code class="computeroutput"><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">object</span></code> from <code class="computeroutput"><span class="identifier">PyObject</span><span class="special">*</span></code>

When you want a <code class="computeroutput"><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">object</span></code> to manage a pointer to <code class="computeroutput"><span class="identifier">PyObject</span><span class="special">*</span></code>

pyobj one does:

</p>

<pre class="programlisting"><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">object</span> <span class="identifier">o</span><span class="special">(</span><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">handle</span><span class="special">&lt;&gt;(</span><span class="identifier">pyobj</span><span class="special">));</span>

In this case, the <code class="computeroutput"><span class="identifier">o</span></code> object,

manages the <code class="computeroutput"><span class="identifier">pyobj</span></code>, it won&#8217;t

increase the reference count on construction.

</p>

Otherwise, to use a borrowed reference:

</p>

<pre class="programlisting"><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">object</span> <span class="identifier">o</span><span class="special">(</span><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">handle</span><span class="special">&lt;&gt;(</span><span class="identifier">boost</span><span class="special">::</span><span class="identifier">python</span><span class="special">::</span><span class="identifier">borrowed</span><span class="special">(</span><span class="identifier">pyobj</span><span class="special">)));</span>

In this case, <code class="computeroutput"><span class="identifier">Py_INCREF</span></code> is

called, so <code class="computeroutput"><span class="identifier">pyobj</span></code> is not destructed

when object o goes out of scope.

</p>

<table xmlns:rev="http://www.cs.rpi.edu/~gregod/boost/tools/doc/revision" width="100%"><tr>

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<td align="right"><div class="copyright-footer">Copyright &#169; 2002-2005 Joel

de Guzman, David Abrahams<p>

Distributed under the Boost Software License, Version 1.0. (See accompanying

file LICENSE_1_0.txt or copy at <a href="http://www.boost.org/LICENSE_1_0.txt" target="_top">

http://www.boost.org/LICENSE_1_0.txt </a>)

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