5. Creating Built Distributions

Note

This document is being retained solely until the setuptools documentation at https://setuptools.readthedocs.io/en/latest/setuptools.html independently covers all of the relevant information currently included here.

A “built distribution” is what you’re probably used to thinking of either as a “binary package” or an “installer” (depending on your background). It’s not necessarily binary, though, because it might contain only Python source code and/or byte-code; and we don’t call it a package, because that word is already spoken for in Python. (And “installer” is a term specific to the world of mainstream desktop systems.)

A built distribution is how you make life as easy as possible for installers of your module distribution: for users of RPM-based Linux systems, it’s a binary RPM; for Windows users, it’s an executable installer; for Debian-based Linux users, it’s a Debian package; and so forth. Obviously, no one person will be able to create built distributions for every platform under the sun, so the Distutils are designed to enable module developers to concentrate on their specialty—writing code and creating source distributions—while an intermediary species called packagers springs up to turn source distributions into built distributions for as many platforms as there are packagers.

Of course, the module developer could be their own packager; or the packager could be a volunteer “out there” somewhere who has access to a platform which the original developer does not; or it could be software periodically grabbing new source distributions and turning them into built distributions for as many platforms as the software has access to. Regardless of who they are, a packager uses the setup script and the bdist command family to generate built distributions.

As a simple example, if I run the following command in the Distutils source tree:

python setup.py bdist

then the Distutils builds my module distribution (the Distutils itself in this case), does a “fake” installation (also in the build directory), and creates the default type of built distribution for my platform. The default format for built distributions is a “dumb” tar file on Unix, and a simple executable installer on Windows. (That tar file is considered “dumb” because it has to be unpacked in a specific location to work.)

Thus, the above command on a Unix system creates Distutils-1.0.plat.tar.gz; unpacking this tarball from the right place installs the Distutils just as though you had downloaded the source distribution and run python setup.py install. (The “right place” is either the root of the filesystem or Python’s prefix directory, depending on the options given to the bdist_dumb command; the default is to make dumb distributions relative to prefix.)

Obviously, for pure Python distributions, this isn’t any simpler than just running python setup.py install—but for non-pure distributions, which include extensions that would need to be compiled, it can mean the difference between someone being able to use your extensions or not. And creating “smart” built distributions, such as an RPM package or an executable installer for Windows, is far more convenient for users even if your distribution doesn’t include any extensions.

The bdist command has a --formats option, similar to the sdist command, which you can use to select the types of built distribution to generate: for example,

python setup.py bdist --format=zip

would, when run on a Unix system, create Distutils-1.0.plat.zip—again, this archive would be unpacked from the root directory to install the Distutils.

The available formats for built distributions are:

Format	Description	Notes
gztar	gzipped tar file (.tar.gz)	(1)
bztar	bzipped tar file (.tar.bz2)
xztar	xzipped tar file (.tar.xz)
ztar	compressed tar file (.tar.Z)	(3)
tar	tar file (.tar)
zip	zip file (.zip)	(2),(4)
rpm	RPM	(5)
pkgtool	Solaris pkgtool
sdux	HP-UX swinstall
msi	Microsoft Installer.

Changed in version 3.5: Added support for the xztar format.

Notes:

1. default on Unix

2. default on Windows

3. requires external compress utility.

4. requires either external zip utility or zipfile module (part of the standard Python library since Python 1.6)

5. requires external rpm utility, version 3.0.4 or better (use rpm --version to find out which version you have)

You don’t have to use the bdist command with the --formats option; you can also use the command that directly implements the format you’re interested in. Some of these bdist “sub-commands” actually generate several similar formats; for instance, the bdist_dumb command generates all the “dumb” archive formats (tar, gztar, bztar, xztar, ztar, and zip), and bdist_rpm generates both binary and source RPMs. The bdist sub-commands, and the formats generated by each, are:

Command	Formats
bdist_dumb	tar, gztar, bztar, xztar, ztar, zip
bdist_rpm	rpm, srpm

The following sections give details on the individual bdist_* commands.

5.1. Creating RPM packages

The RPM format is used by many popular Linux distributions, including Red Hat, SuSE, and Mandrake. If one of these (or any of the other RPM-based Linux distributions) is your usual environment, creating RPM packages for other users of that same distribution is trivial. Depending on the complexity of your module distribution and differences between Linux distributions, you may also be able to create RPMs that work on different RPM-based distributions.

The usual way to create an RPM of your module distribution is to run the bdist_rpm command:

python setup.py bdist_rpm

or the bdist command with the --format option:

python setup.py bdist --formats=rpm

The former allows you to specify RPM-specific options; the latter allows you to easily specify multiple formats in one run. If you need to do both, you can explicitly specify multiple bdist_* commands and their options:

python setup.py bdist_rpm --packager="John Doe <jdoe@example.org>"

Creating RPM packages is driven by a .spec file, much as using the Distutils is driven by the setup script. To make your life easier, the bdist_rpm command normally creates a .spec file based on the information you supply in the setup script, on the command line, and in any Distutils configuration files. Various options and sections in the .spec file are derived from options in the setup script as follows:

RPM .spec file option or section	Distutils setup script option
Name	name
Summary (in preamble)	description
Version	version
Vendor	author and author_email, or — & maintainer and maintainer_email
Copyright	license
Url	url
%description (section)	long_description

Additionally, there are many options in .spec files that don’t have corresponding options in the setup script. Most of these are handled through options to the bdist_rpm command as follows:

RPM .spec file option or section	bdist_rpm option	default value
Release	release	“1”
Group	group	“Development/Libraries”
Vendor	vendor	(see above)
Packager	packager	(none)
Provides	provides	(none)
Requires	requires	(none)
Conflicts	conflicts	(none)
Obsoletes	obsoletes	(none)
Distribution	distribution_name	(none)
BuildRequires	build_requires	(none)
Icon	icon	(none)

Obviously, supplying even a few of these options on the command-line would be tedious and error-prone, so it’s usually best to put them in the setup configuration file, setup.cfg—see section Writing the Setup Configuration File. If you distribute or package many Python module distributions, you might want to put options that apply to all of them in your personal Distutils configuration file (~/.pydistutils.cfg). If you want to temporarily disable this file, you can pass the --no-user-cfg option to setup.py.

There are three steps to building a binary RPM package, all of which are handled automatically by the Distutils:

1. create a .spec file, which describes the package (analogous to the Distutils setup script; in fact, much of the information in the setup script winds up in the .spec file)

2. create the source RPM

3. create the “binary” RPM (which may or may not contain binary code, depending on whether your module distribution contains Python extensions)

Normally, RPM bundles the last two steps together; when you use the Distutils, all three steps are typically bundled together.

If you wish, you can separate these three steps. You can use the --spec-only option to make bdist_rpm just create the .spec file and exit; in this case, the .spec file will be written to the “distribution directory”—normally dist/, but customizable with the --dist-dir option. (Normally, the .spec file winds up deep in the “build tree,” in a temporary directory created by bdist_rpm.)

5.2. Cross-compiling on Windows

Starting with Python 2.6, distutils is capable of cross-compiling between Windows platforms. In practice, this means that with the correct tools installed, you can use a 32bit version of Windows to create 64bit extensions and vice-versa.

To build for an alternate platform, specify the --plat-name option to the build command. Valid values are currently ‘win32’, and ‘win-amd64’. For example, on a 32bit version of Windows, you could execute:

python setup.py build --plat-name=win-amd64

to build a 64bit version of your extension.

would create a 64bit installation executable on your 32bit version of Windows.

To cross-compile, you must download the Python source code and cross-compile Python itself for the platform you are targeting - it is not possible from a binary installation of Python (as the .lib etc file for other platforms are not included.) In practice, this means the user of a 32 bit operating system will need to use Visual Studio 2008 to open the PCbuild/PCbuild.sln solution in the Python source tree and build the “x64” configuration of the ‘pythoncore’ project before cross-compiling extensions is possible.

Note that by default, Visual Studio 2008 does not install 64bit compilers or tools. You may need to reexecute the Visual Studio setup process and select these tools (using Control Panel->[Add/Remove] Programs is a convenient way to check or modify your existing install.)

5.2.1. The Postinstallation script

Starting with Python 2.3, a postinstallation script can be specified with the --install-script option. The basename of the script must be specified, and the script filename must also be listed in the scripts argument to the setup function.

This script will be run at installation time on the target system after all the files have been copied, with argv[1] set to -install, and again at uninstallation time before the files are removed with argv[1] set to -remove.

The installation script runs embedded in the windows installer, every output (sys.stdout, sys.stderr) is redirected into a buffer and will be displayed in the GUI after the script has finished.

Some functions especially useful in this context are available as additional built-in functions in the installation script.

directory_created(path)

file_created(path)

These functions should be called when a directory or file is created by the postinstall script at installation time. It will register path with the uninstaller, so that it will be removed when the distribution is uninstalled. To be safe, directories are only removed if they are empty.

get_special_folder_path(csidl_string)

This function can be used to retrieve special folder locations on Windows like the Start Menu or the Desktop. It returns the full path to the folder. csidl_string must be one of the following strings:

"CSIDL_APPDATA"

"CSIDL_COMMON_STARTMENU"
"CSIDL_STARTMENU"

"CSIDL_COMMON_DESKTOPDIRECTORY"
"CSIDL_DESKTOPDIRECTORY"

"CSIDL_COMMON_STARTUP"
"CSIDL_STARTUP"

"CSIDL_COMMON_PROGRAMS"
"CSIDL_PROGRAMS"

"CSIDL_FONTS"

If the folder cannot be retrieved, OSError is raised.

Which folders are available depends on the exact Windows version, and probably also the configuration. For details refer to Microsoft’s documentation of the SHGetSpecialFolderPath() function.

create_shortcut(target, description, filename[, arguments[, workdir[, iconpath[, iconindex]]]])

This function creates a shortcut. target is the path to the program to be started by the shortcut. description is the description of the shortcut. filename is the title of the shortcut that the user will see. arguments specifies the command line arguments, if any. workdir is the working directory for the program. iconpath is the file containing the icon for the shortcut, and iconindex is the index of the icon in the file iconpath. Again, for details consult the Microsoft documentation for the IShellLink interface.