305 lines
13 KiB
ReStructuredText
305 lines
13 KiB
ReStructuredText
.. _packaging-built-dist:
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****************************
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Creating Built Distributions
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****************************
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A "built distribution" is what you're probably used to thinking of either as a
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"binary package" or an "installer" (depending on your background). It's not
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necessarily binary, though, because it might contain only Python source code
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and/or byte-code; and we don't call it a package, because that word is already
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spoken for in Python. (And "installer" is a term specific to the world of
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mainstream desktop systems.)
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A built distribution is how you make life as easy as possible for installers of
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your module distribution: for users of RPM-based Linux systems, it's a binary
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RPM; for Windows users, it's an executable installer; for Debian-based Linux
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users, it's a Debian package; and so forth. Obviously, no one person will be
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able to create built distributions for every platform under the sun, so the
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Distutils are designed to enable module developers to concentrate on their
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specialty---writing code and creating source distributions---while an
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intermediary species called *packagers* springs up to turn source distributions
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into built distributions for as many platforms as there are packagers.
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Of course, the module developer could be his own packager; or the packager could
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be a volunteer "out there" somewhere who has access to a platform which the
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original developer does not; or it could be software periodically grabbing new
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source distributions and turning them into built distributions for as many
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platforms as the software has access to. Regardless of who they are, a packager
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uses the setup script and the :command:`bdist` command family to generate built
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distributions.
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As a simple example, if I run the following command in the Distutils source
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tree::
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python setup.py bdist
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then the Distutils builds my module distribution (the Distutils itself in this
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case), does a "fake" installation (also in the :file:`build` directory), and
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creates the default type of built distribution for my platform. The default
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format for built distributions is a "dumb" tar file on Unix, and a simple
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executable installer on Windows. (That tar file is considered "dumb" because it
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has to be unpacked in a specific location to work.)
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Thus, the above command on a Unix system creates
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:file:`Distutils-1.0.{plat}.tar.gz`; unpacking this tarball from the right place
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installs the Distutils just as though you had downloaded the source distribution
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and run ``python setup.py install``. (The "right place" is either the root of
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the filesystem or Python's :file:`{prefix}` directory, depending on the options
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given to the :command:`bdist_dumb` command; the default is to make dumb
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distributions relative to :file:`{prefix}`.)
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Obviously, for pure Python distributions, this isn't any simpler than just
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running ``python setup.py install``\ ---but for non-pure distributions, which
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include extensions that would need to be compiled, it can mean the difference
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between someone being able to use your extensions or not. And creating "smart"
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built distributions, such as an executable installer for
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Windows, is far more convenient for users even if your distribution doesn't
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include any extensions.
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The :command:`bdist` command has a :option:`--formats` option, similar to the
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:command:`sdist` command, which you can use to select the types of built
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distribution to generate: for example, ::
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python setup.py bdist --format=zip
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would, when run on a Unix system, create :file:`Distutils-1.0.{plat}.zip`\
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---again, this archive would be unpacked from the root directory to install the
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Distutils.
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The available formats for built distributions are:
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+-------------+------------------------------+---------+
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| Format | Description | Notes |
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+=============+==============================+=========+
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| ``gztar`` | gzipped tar file | (1),(3) |
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| | (:file:`.tar.gz`) | |
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+-------------+------------------------------+---------+
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| ``tar`` | tar file (:file:`.tar`) | \(3) |
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+-------------+------------------------------+---------+
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| ``zip`` | zip file (:file:`.zip`) | (2),(4) |
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+-------------+------------------------------+---------+
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| ``wininst`` | self-extracting ZIP file for | \(4) |
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| | Windows | |
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+-------------+------------------------------+---------+
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| ``msi`` | Microsoft Installer. | |
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+-------------+------------------------------+---------+
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Notes:
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(1)
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default on Unix
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(2)
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default on Windows
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(3)
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requires external utilities: :program:`tar` and possibly one of :program:`gzip`
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or :program:`bzip2`
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(4)
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requires either external :program:`zip` utility or :mod:`zipfile` module (part
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of the standard Python library since Python 1.6)
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You don't have to use the :command:`bdist` command with the :option:`--formats`
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option; you can also use the command that directly implements the format you're
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interested in. Some of these :command:`bdist` "sub-commands" actually generate
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several similar formats; for instance, the :command:`bdist_dumb` command
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generates all the "dumb" archive formats (``tar``, ``gztar``, and
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``zip``). The :command:`bdist` sub-commands, and the formats generated by
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each, are:
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+--------------------------+-----------------------+
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| Command | Formats |
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+==========================+=======================+
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| :command:`bdist_dumb` | tar, gztar, zip |
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+--------------------------+-----------------------+
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| :command:`bdist_wininst` | wininst |
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+--------------------------+-----------------------+
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| :command:`bdist_msi` | msi |
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+--------------------------+-----------------------+
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The following sections give details on the individual :command:`bdist_\*`
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commands.
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.. _packaging-creating-dumb:
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Creating dumb built distributions
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=================================
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.. XXX Need to document absolute vs. prefix-relative packages here, but first
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I have to implement it!
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.. _packaging-creating-wininst:
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Creating Windows Installers
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===========================
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Executable installers are the natural format for binary distributions on
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Windows. They display a nice graphical user interface, display some information
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about the module distribution to be installed taken from the metadata in the
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setup script, let the user select a few options, and start or cancel the
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installation.
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Since the metadata is taken from the setup script, creating Windows installers
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is usually as easy as running::
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python setup.py bdist_wininst
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or the :command:`bdist` command with the :option:`--formats` option::
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python setup.py bdist --formats=wininst
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If you have a pure module distribution (only containing pure Python modules and
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packages), the resulting installer will be version independent and have a name
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like :file:`foo-1.0.win32.exe`. These installers can even be created on Unix
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platforms or Mac OS X.
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If you have a non-pure distribution, the extensions can only be created on a
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Windows platform, and will be Python version dependent. The installer filename
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will reflect this and now has the form :file:`foo-1.0.win32-py2.0.exe`. You
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have to create a separate installer for every Python version you want to
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support.
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.. TODO Add :term: markup to bytecode when merging into the stdlib
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The installer will try to compile pure modules into bytecode after installation
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on the target system in normal and optimizing mode. If you don't want this to
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happen for some reason, you can run the :command:`bdist_wininst` command with
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the :option:`--no-target-compile` and/or the :option:`--no-target-optimize`
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option.
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By default the installer will display the cool "Python Powered" logo when it is
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run, but you can also supply your own 152x261 bitmap which must be a Windows
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:file:`.bmp` file with the :option:`--bitmap` option.
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The installer will also display a large title on the desktop background window
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when it is run, which is constructed from the name of your distribution and the
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version number. This can be changed to another text by using the
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:option:`--title` option.
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The installer file will be written to the "distribution directory" --- normally
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:file:`dist/`, but customizable with the :option:`--dist-dir` option.
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.. _packaging-cross-compile-windows:
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Cross-compiling on Windows
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==========================
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Starting with Python 2.6, packaging is capable of cross-compiling between
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Windows platforms. In practice, this means that with the correct tools
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installed, you can use a 32bit version of Windows to create 64bit extensions
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and vice-versa.
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To build for an alternate platform, specify the :option:`--plat-name` option
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to the build command. Valid values are currently 'win32', 'win-amd64' and
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'win-ia64'. For example, on a 32bit version of Windows, you could execute::
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python setup.py build --plat-name=win-amd64
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to build a 64bit version of your extension. The Windows Installers also
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support this option, so the command::
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python setup.py build --plat-name=win-amd64 bdist_wininst
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would create a 64bit installation executable on your 32bit version of Windows.
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To cross-compile, you must download the Python source code and cross-compile
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Python itself for the platform you are targetting - it is not possible from a
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binary installtion of Python (as the .lib etc file for other platforms are
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not included.) In practice, this means the user of a 32 bit operating
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system will need to use Visual Studio 2008 to open the
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:file:`PCBuild/PCbuild.sln` solution in the Python source tree and build the
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"x64" configuration of the 'pythoncore' project before cross-compiling
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extensions is possible.
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Note that by default, Visual Studio 2008 does not install 64bit compilers or
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tools. You may need to reexecute the Visual Studio setup process and select
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these tools (using Control Panel->[Add/Remove] Programs is a convenient way to
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check or modify your existing install.)
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.. _packaging-postinstallation-script:
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The Postinstallation script
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---------------------------
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Starting with Python 2.3, a postinstallation script can be specified with the
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:option:`--install-script` option. The basename of the script must be
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specified, and the script filename must also be listed in the scripts argument
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to the setup function.
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This script will be run at installation time on the target system after all the
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files have been copied, with ``argv[1]`` set to :option:`-install`, and again at
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uninstallation time before the files are removed with ``argv[1]`` set to
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:option:`-remove`.
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The installation script runs embedded in the windows installer, every output
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(``sys.stdout``, ``sys.stderr``) is redirected into a buffer and will be
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displayed in the GUI after the script has finished.
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Some functions especially useful in this context are available as additional
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built-in functions in the installation script.
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.. currentmodule:: bdist_wininst-postinst-script
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.. function:: directory_created(path)
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file_created(path)
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These functions should be called when a directory or file is created by the
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postinstall script at installation time. It will register *path* with the
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uninstaller, so that it will be removed when the distribution is uninstalled.
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To be safe, directories are only removed if they are empty.
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.. function:: get_special_folder_path(csidl_string)
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This function can be used to retrieve special folder locations on Windows like
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the Start Menu or the Desktop. It returns the full path to the folder.
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*csidl_string* must be one of the following strings::
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"CSIDL_APPDATA"
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"CSIDL_COMMON_STARTMENU"
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"CSIDL_STARTMENU"
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"CSIDL_COMMON_DESKTOPDIRECTORY"
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"CSIDL_DESKTOPDIRECTORY"
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"CSIDL_COMMON_STARTUP"
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"CSIDL_STARTUP"
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"CSIDL_COMMON_PROGRAMS"
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"CSIDL_PROGRAMS"
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"CSIDL_FONTS"
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If the folder cannot be retrieved, :exc:`OSError` is raised.
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Which folders are available depends on the exact Windows version, and probably
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also the configuration. For details refer to Microsoft's documentation of the
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:c:func:`SHGetSpecialFolderPath` function.
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.. function:: create_shortcut(target, description, filename[, arguments[, workdir[, iconpath[, iconindex]]]])
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This function creates a shortcut. *target* is the path to the program to be
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started by the shortcut. *description* is the description of the shortcut.
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*filename* is the title of the shortcut that the user will see. *arguments*
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specifies the command-line arguments, if any. *workdir* is the working directory
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for the program. *iconpath* is the file containing the icon for the shortcut,
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and *iconindex* is the index of the icon in the file *iconpath*. Again, for
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details consult the Microsoft documentation for the :class:`IShellLink`
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interface.
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Vista User Access Control (UAC)
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===============================
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Starting with Python 2.6, bdist_wininst supports a :option:`--user-access-control`
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option. The default is 'none' (meaning no UAC handling is done), and other
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valid values are 'auto' (meaning prompt for UAC elevation if Python was
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installed for all users) and 'force' (meaning always prompt for elevation).
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