<html>  <head>    <title>Python for .NET</title>    <style type="text/css"><!--body {   font: 8pt/16pt georgia,verdana;   text-decoration: none;  color: #555753;   background: #ffffff;  margin: 0px; }p {   font: 8pt/16pt georgia; }h1 {   font: bold 14pt;  color: #000044;/*  background-color: #EFEFFF;  color: #000044;  border-style: solid;  border-width: 1px;  border-color: #555753;  padding: 6px, 2px, 6px, 2px;*/}h2 {   font: bold 14pt;  margin-bottom: 0px;   color: #000044;}h3 {   font: bold 12pt;  margin-bottom: 0px;  color: #000044; }a:link {   font-weight: bold;   text-decoration: none;   color: #000066;}a:visited {   font-weight: bold;   text-decoration: none;   color: #000066;}a:hover, a:active {   text-decoration: underline;   color: #000066;}pre {  font-family: monospace;  background-color: #EFEFFF;  color: #000044;  border-style: solid;  border-width: 1px;  border-color: #555753;  padding: 6px, 2px, 6px, 2px;}li {   font: 8pt/16pt georgia,verdana;   text-decoration: none;  color: #555753; }.spacer {  font: bold 14pt;}.menu {  background-color: #EFEFFF;  color: #000044;  border-style: solid;  border-width: 1px;  border-color: #555753;  padding: 6px, 2px, 6px, 2px;  font-size: x-small;}.menu ul {  margin: 0px;  padding: 0px;}//--></style>    <meta content="text/html; charset=ISO-8859-1" http-equiv="content-type">  </head>  <body>    <table border="0" cellspacing="4" width="98%">      <tbody>        <tr>          <td align="left" valign="top" width="20%">            <h1>Python for .NET</h1>            <ul>              <li><a href="#installation">Installation</a></li>              <li><a href="#getting_started">Getting Started</a></li>              <li><a href="#importing">Importing Modules</a></li>              <li><a href="#classes">Using Classes</a></li>              <li><a href="#generics">Using Generics</a></li>              <li><a href="#fields">Fields and Properties</a></li>              <li><a href="#indexers">Using Indexers</a></li>              <li><a href="#methods">Using Methods</a></li>              <li><a href="#genericmethods">Overloaded and Generic Methods</a></li>              <li><a href="#delegates">Delegates and Events</a></li>              <li><a href="#exceptions">Exception Handling</a></li>              <li><a href="#arrays">Using Arrays</a></li>              <li><a href="#collections">Using Collections</a></li>              <li><a href="#com">COM Components</a></li>              <li><a href="#types">Type Conversion</a></li>              <li><a href="#embedding">Embedding Python</a></li>              <li><a href="#license">License</a></li>            </ul>          </td>          <td align="left" valign="top">            <p> Python for .NET is a package that gives Python programmers              nearly seamless integration with the .NET Common Language Runtime              (CLR) and provides a powerful application scripting tool for .NET              developers. Using this package you can script .NET applications or              build entire applications in Python, using .NET services and              components written in any language that targets the CLR (Managed              C++, C#, VB, JScript).            </p>            <p> Note that this package does <em>not</em> implement Python as a              first-class CLR language - it does not produce managed code (IL)              from Python code. Rather, it is an integration of the C Python              engine with the .NET runtime. This approach allows you to use use              CLR services and continue to use existing Python code and C-based              extensions while maintaining native execution speeds for Python              code. If you are interested in a pure managed-code implementation              of the Python language, you should check out the <a href="http://www.ironpython.com">IronPython</a>              project, which is in active development.            </p>            <p> Python for .NET is currently compatible with Python releases 2.3              and greater. Current releases are available at the <a href="http://pythonnet.sourceforge.net/">                Python for .NET website </a>. To subscribe to the <a href="http://mail.python.org/mailman/listinfo/pythondotnet">                Python for .NET mailing list </a> or read the <a href="http://mail.python.org/pipermail/pythondotnet/">                online archives </a> of the list, see the <a href="http://mail.python.org/mailman/listinfo/pythondotnet">                mailing list information </a> page. </p>            <a name="#installation"></a>            <h2>Installation</h2>            <p> Python for .NET is available as a source release and as a              Windows installer for various versions of Python and the common              language runtime from the <a href="http://pythonnet.sourceforge.net/">                Python for .NET website </a>. On Windows platforms, you can              choose to install .NET-awareness into an existing Python              installation as well as install Python for .NET as a standalone              package.            </p>                        <p> The source release is a self-contained "private" assembly. Just              unzip the package wherever you want it, cd to that directory and              run python.exe to start using it. Note that the source release              does not include a copy of the CPython runtime, so you will need              to have installed Python on your machine before using the source              release.            </p>            <p> <strong>Running on Linux/Mono:</strong> preliminary testing              shows that PythonNet will run under <a href="http://www.go-mono.com">Mono</a>,              though the Mono runtime is not yet complete so there still may be              problems. The Python for .NET integration layer is 100% managed              code, so there should be no long-term issues under Mono - it              should work better and better as the Mono platform matures.            </p>            <p> Note that if you are running under Mono on a *nix system, you              will need to have a compatible version of Python installed. You              will also need to create a symbolic link to the copy of              libpython2.x.so (in your existing Python installation) in the              PythonNet directory. This is needed to ensure that the mono              interop dll loader will find it by name. For example:            </p>            <pre>    ln -s /usr/lib/libpython2.4.so ./python24.so</pre>            <a name="getting_started"></a>            <h2>Getting Started</h2>            <p> A key goal for this project has been that Python for .NET should              "work just the way you'd expect in Python", except for cases that              are .NET specific (in which case the goal is to work "just the way              you'd expect in C#"). In addition, with the IronPython project              gaining traction, it is my goal that code written for IronPython              run without modification under Python for .NET.            </p>            <p> If you already know Python, you can probably finish this readme              and then refer to .NET docs to figure out anything you need to do.              Conversely if you are familiar with C# or another .NET language,              you probably just need to pick up one of the many good Python              books or read the Python tutorial online to get started.            </p>            <p> A good way to start is to run <strong>python.exe</strong> and              follow along with the examples in this document. If you get stuck,              there are also a number of demos and unit tests located in the              source directory of the distribution that can be helpful as              examples.            </p>            <p> Note that if you have installed CLR support into your existing              Python installation (rather than using the included python.exe),              you will need to use the line: "'import clr" (lower-case!) to              initially load the clr extension module before trying the              following examples.            </p>            <a name="importing"></a>            <h2>Importing Modules</h2>            <p> Python for .NET allows CLR namespaces to be treated essentially              as Python packages. </p>            <p>            </p>            <pre>    from System import String    from System.Collections import *</pre>            <p>              <em> Note that earlier releases of Python for .NET required you to                import modules through a special top-level package named <code>CLR</code>.                This is no longer required if you are starting python from the                managed python.exe from this distribution.<br>                <code>CLR</code> has been deprecated in favor of the more                pythonic <code>clr</code>, though the syntax is still supported                for backward compatibility.              </em>            </p>            <p> Types from any loaded assembly may be imported and used in this              manner. To load an assembly, use the "AddReference" function in              the "clr" module:            </p>            <pre>    import clr    clr.AddReference("System.Windows.Forms")    from System.Windows.Forms import Form</pre>            <p>              <em> Note that earlier releases of Python for .NET relied on                "implicit loading" to support automatic loading of assemblies                whose names corresponded to an imported namespace. Implicit                loading still works for backward compatibility, but will be                removed in a future release so it is recommended to use the                clr.AddReference method.              </em>            </p>            <p> Python for .NET uses the PYTHONPATH (sys.path) to look for              assemblies to load, in addition to the usual application base and              the GAC. To ensure that you can implicitly import an assembly, put              the directory containing the assembly in <code>sys.path</code>.            </p>            <a name="classes"></a>            <h2>Using Classes</h2>            <p> Python for .NET allows you to use any non-private classes,              structs, interfaces, enums or delegates from Python. To create an              instance of a managed class, you use the standard instantiation              syntax, passing a set of arguments that match one of its public              constructors:            </p>            <pre>    from System.Drawing import Point    p = Point(5, 5)</pre>            <p> In most cases, Python for .NET can determine the correct              constructor to call automatically based on the arguments. In some              cases, it may be necessary to call a particular overloaded              constructor, which is supported by a special "__overloads__"              attribute, which will soon be deprecated in favor of iPy              compatible "Overloads", on a class:            </p>            <pre>    from System import String, Char, Int32    s = String.Overloads[Char, Int32]('A', 10)    s = String.__overloads__[Char, Int32]('A', 10)</pre>            <a name="generics"></a>            <h2>Using Generics</h2>            <p> When running under versions of the .NET runtime greater than              2.0, you can use generic types. A generic type must be bound to              create a concrete type before it can be instantiated. Generic              types support the subscript syntax to create bound types:            </p>            <pre>    from System.Collections.Generic import Dictionary    from System import *    dict1 = Dictionary[String, String]()    dict2 = Dictionary[String, Int32]()    dict3 = Dictionary[String, Type]()</pre>            <p> When you pass a list of types using the subscript syntax, you              can also pass a subset of Python types that directly correspond to              .NET types:            </p>            <pre>    dict1 = Dictionary[str, str]()    dict2 = Dictionary[str, int]()    dict3 = Dictionary[str, Decimal]()</pre>            <p> This shorthand also works when explicitly selecting generic              methods or specific versions of overloaded methods and              constructors (explained later).            </p>            <p> You can also subclass managed classes in Python, though members              of the Python subclass are not visible to .NET code. See the <code>helloform.py</code>              file in the <code>/demo</code> directory of the distribution for              a simple Windows Forms example that demonstrates subclassing a              managed class.            </p>            <a name="fields"></a>            <h2>Fields And Properties</h2>            <p> You can get and set fields and properties of CLR objects just as              if they were regular attributes:            </p>            <pre>    from System import Environment    name = Environment.MachineName    Environment.ExitCode = 1</pre>            <a name="indexers"></a>            <h2>Using Indexers</h2>            <p> If a managed object implements one or more indexers, you can              call the indexer using standard Python indexing syntax:            </p>            <pre>    from System.Collections import Hashtable    table = Hashtable()    table["key 1"] = "value 1"</pre>            <p> Overloaded indexers are supported, using the same notation one              would use in C#:            </p>            <pre>    items[0, 2]    items[0, 2, 3]</pre>            <a name="methods"></a>            <h2>Using Methods</h2>            <p> Methods of CLR objects behave generally like normal Python              methods. Static methods may be called either through the class or              through an instance of the class. All public and protected methods              of CLR objects are accessible to Python:            </p>            <pre>    from System import Environment    drives = Environment.GetLogicalDrives()</pre>            <p> It is also possible to call managed methods <code>unbound</code>              (passing the instance as the first argument) just as with Python              methods. This is most often used to explicitly call methods of a              base class.            </p>            <p> <em>Note that there is one caveat related to calling unbound                methods: it is possible for a managed class to declare a static                method and an instance method with the same name. Since it is                not possible for the runtime to know the intent when such a                method is called unbound, the static method will always be                called.</em>            </p>            <p> The docstring of CLR a method (__doc__) can be used to view the              signature of the method, including overloads if the CLR method is              overloaded. You can also use the Python <code>help</code> method              to inspect a managed class:            </p>            <pre>    from System import Environment    print Environment.GetFolderPath.__doc__    help(Environment)</pre>            <a name="genericmethods"></a>            <h2>Overloaded and Generic Methods</h2>            <p> While Python for .NET will generally be able to figure out the              right version of an overloaded method to call automatically, there              are cases where it is desirable to select a particular method              overload explicitly.            </p>            <p> Methods of CLR objects have an "__overloads__", which will soon              be deprecated in favor of iPy compatible Overloads, attribute that              can be used for this purpose :            </p>            <pre>    from System import Console    Console.WriteLine.Overloads[bool](true)    Console.WriteLine.Overloads[str]("true")    Console.WriteLine.__overloads__[int](42)</pre>            <p> Similarly, generic methods may be bound at runtime using the              subscript syntax directly on the method:            </p>            <pre>    someobject.SomeGenericMethod[int](10)    someobject.SomeGenericMethod[str]("10")</pre>            <a name="delegates"></a>            <h2>Delegates And Events</h2>            <p> Delegates defined in managed code can be implemented in Python.              A delegate type can be instantiated and passed a callable Python              object to get a delegate instance. The resulting delegate instance              is a true managed delegate that will invoke the given Python              callable when it is called:            </p>            <pre>    def my_handler(source, args):        print 'my_handler called!'    # instantiate a delegate    d = AssemblyLoadEventHandler(my_handler)    # use it as an event handler    AppDomain.CurrentDomain.AssemblyLoad += d</pre>            <p> Multicast delegates can be implemented by adding more callable              objects to a delegate instance:            </p>            <pre>    d += self.method1    d += self.method2    d()</pre>            <p> Events are treated as first-class objects in Python, and behave              in many ways like methods. Python callbacks can be registered with              event attributes, and an event can be called to fire the event.            </p>            <p> Note that events support a convenience spelling similar to that              used in C#. You do not need to pass an explicitly instantiated              delegate instance to an event (though you can if you want). Events              support the <code>+=</code> and <code>-=</code> operators in a              way very similar to the C# idiom:            </p>            <pre>    def handler(source, args):        print 'my_handler called!'    # register event handler    object.SomeEvent += handler    # unregister event handler    object.SomeEvent -= handler    # fire the event    result = object.SomeEvent(...)</pre>            <a name="exceptions"></a>            <h2>Exception Handling</h2>            <p> You can raise and catch managed exceptions just the same as you              would pure-Python exceptions:            </p>            <pre>    from System import NullReferenceException    try:        raise NullReferenceException("aiieee!")    except NullReferenceException, e:        print e.Message        print e.Source</pre>            <p></p>            <a name="arrays"></a>            <h2>Using Arrays</h2>            <p> The type <code>System.Array</code> supports the subscript              syntax in order to make it easy to create managed arrays from              Python:            </p>            <pre>    from System import Array    myarray = Array[int](10)</pre>            <p> Managed arrays support the standard Python sequence protocols:            </p>            <pre>    items = SomeObject.GetArray()    # Get first item    v = items[0]    items[0] = v    # Get last item    v = items[-1]    items[-1] = v    # Get length    l = len(items)    # Containment test    test = v in items</pre>            <p> Multidimensional arrays support indexing using the same notation              one would use in C#:            </p>            <pre>    items[0, 2]    items[0, 2, 3]</pre>            <a name="collections"></a>            <h2>Using Collections</h2>            <p> Managed arrays and managed objects that implement the              IEnumerable interface can be iterated over using the standard              iteration Python idioms:            </p>            <pre>    domain = System.AppDomain.CurrentDomain    for item in domain.GetAssemblies():        name = item.GetName()</pre>            <a name="com"></a>            <h2>Using COM Components</h2>            <p> Using Microsoft-provided tools such as <strong>aximp.exe</strong>              and <strong>tlbimp.exe</strong>, it is possible to generate              managed wrappers for COM libraries. After generating such a              wrapper, you can use the libraries from Python just like any other              managed code.            </p>            <p> Note: currently you need to put the generated wrappers in the              GAC, in the PythonNet assembly directory or on the PYTHONPATH in              order to load them.            </p>            <a name="types"></a>            <h2>Type Conversion</h2>            <p> Type conversion under Python for .NET is fairly straightforward              - most elemental Python types (string, int, long, etc.) convert              automatically to compatible managed equivalents (String, Int32,              etc.) and vice-versa. Note that all strings returned from the CLR              are returned as unicode.            </p>            <p> Types that do not have a logical equivalent in Python are              exposed as instances of managed classes or structs (System.Decimal              is an example).            </p>            <p> The .NET architecture makes a distinction between <code>value                types</code> and <code>reference types</code>. Reference types              are allocated on the heap, and value types are allocated either on              the stack or in-line within an object.            </p>            <p> A process called <code>boxing</code> is used in .NET to allow              code to treat a value type as if it were a reference type. Boxing              causes a separate copy of the value type object to be created on              the heap, which then has reference type semantics.            </p>            <p> Understanding boxing and the distinction between value types and              reference types can be important when using Python for .NET              because the Python language has no value type semantics or syntax              - in Python "everything is a reference".            </p>            <p> Here is a simple example that demonstrates an issue. If you are              an experienced C# programmer, you might write the following code:            </p>            <pre>    items = System.Array.CreateInstance(Point, 3)    for i in range(3):        items[i] = Point(0, 0)    items[0].X = 1 # won't work!!</pre>            <p> While the spelling of <code>items[0].X = 1</code> is the same              in C# and Python, there is an important and subtle semantic              difference. In C# (and other compiled-to-IL languages), the              compiler knows that Point is a value type and can do the Right              Thing here, changing the value in place.            </p>            <p> In Python however, "everything's a reference", and there is              really no spelling or semantic to allow it to do the right thing              dynamically. The specific reason that <code>items[0]</code>              itself doesn't change is that when you say <code>items[0]</code>,              that getitem operation creates a Python object that holds a              reference to the object at <code>items[0]</code> via a GCHandle.              That causes a ValueType (like Point) to be boxed, so the following              setattr (<code>.X = 1</code>) <em>changes the state of the boxed                value, not the original unboxed value</em>.            </p>            <p> The rule in Python is essentially: "the result of any attribute              or item access is a boxed value", and that can be important in how              you approach your code.            </p>            <p> Because there are no value type semantics or syntax in Python,              you may need to modify your approach. To revisit the previous              example, we can ensure that the changes we want to make to an              array item aren't "lost" by resetting an array member after making              changes to it:            </p>            <pre>    items = System.Array.CreateInstance(Point, 3)    for i in range(3):        items[i] = Point(0, 0)    # This _will_ work. We get 'item' as a boxed copy of the Point    # object actually stored in the array. After making our changes    # we re-set the array item to update the bits in the array.    item = items[0]    item.X = 1    items[0] = item</pre>            <p> This is not unlike some of the cases you can find in C# where              you have to know about boxing behavior to avoid similar kinds of <code>lost                update</code> problems (generally because an implicit boxing              happened that was not taken into account in the code).            </p>            <p> This is the same thing, just the manifestation is a little              different in Python. See the .NET documentation for more details              on boxing and the differences between value types and reference              types.            </p>            <a name="embedding"></a>            <h2>Embedding Python</h2>            <p> <strong>Note:</strong> because Python code running under Python              for .NET is inherently unverifiable, it runs totally under the              radar of the security infrastructure of the CLR so you should              restrict use of the Python assembly to trusted code.            </p>            <p> The Python runtime assembly defines a number of public classes              that provide a subset of the functionality provided by the Python              C API.            </p>            <p> These classes include PyObject, PyList, PyDict, etc. The source              and the unit tests are currently the only API documentation.. The              rhythym is very similar to using Python C++ wrapper solutions such              as CXX.            </p>            <p> At a very high level, to embed Python in your application you              will need to:            </p>            <ul>              <li>Reference Python.Runtime.dll in your build environment</li>              <li>Call PythonEngine.Intialize() to initialize Python</li>              <li>Call PythonEngine.ImportModule(name) to import a module</li>            </ul>            <p> The module you import can either start working with your managed              app environment at the time its imported, or you can explicitly              lookup and call objects in a module you import.            </p>            <p> For general-purpose information on embedding Python in              applications, usewww.python.org or Google to find (C) examples.              Because Python for .NET is so closely integrated with the managed              environment, you will generally be better off importing a module              and deferring to Python code as early as possible rather than              writing a lot of managed embedding code.            </p>            <p> <strong>Important Note for embedders:</strong> Python is not              free-threaded and uses a global interpreter lock to allow              multi-threaded applications to interact safely with the Python              interpreter. Much more information about this is available in the              Python C API documentation on thewww.python.org Website.            </p>            <p> When embedding Python in a managed application, you have to              manage the GIL in just the same way you would when embedding              Python in a C or C++ application.            </p>            <p> Before interacting with any of the objects or APIs provided by              the Python.Runtime namespace, calling code must have acquired the              Python global interpreter lock by calling the <code>PythonEngine.AcquireLock</code>              method. The only exception to this rule is the <code>PythonEngine.Initialize</code>              method, which may be called at startup without having acquired the              GIL.            </p>            <p> When finished using Python APIs, managed code must call a              corresponding <code>PythonEngine.ReleaseLock</code> to release              the GIL and allow other threads to use Python.            </p>            <p> The AcquireLock and ReleaseLock methods are thin wrappers over              the unmanaged <code>PyGILState_Ensure</code> and <code>PyGILState_Release</code>              functions from the Python API, and the documentation for those              APIs applies to the managed versions.            </p>            <a name="license">              <h2>License</h2>            </a>            <p><a name="license"> Python for .NET is released under the open                source Zope Public License (ZPL). A copy of the ZPL is included                in the distribution, or you can find a copy of the </a><a href="http://pythonnet.sourceforge.net/license.txt">                ZPL online </a>. Some distributions of this package include a              copy of the C Python dlls and standard library, which are covered              by the <a href="http://www.python.org/license.html"> Python                license </a>.            </p>          </td>        </tr>      </tbody>    </table>  </body></html>