====================================================== Building and Distributing Packages with ``setuptools`` ====================================================== ``setuptools`` is a collection of enhancements to the Python ``distutils`` (for Python 2.3 and up) that allow you to more easily build and distribute Python packages, especially ones that have dependencies on other packages. Packages built and distributed using ``setuptools`` look to the user like ordinary Python packages based on the ``distutils``. Your users don't need to install or even know about setuptools in order to use them, and you don't have to include the entire setuptools package in your distributions. By including just a single `bootstrap module`_ (a 5K .py file), your package will automatically download and install ``setuptools`` if the user is building your package from source and doesn't have a suitable version already installed. .. _bootstrap module: http://peak.telecommunity.com/dist/ez_setup.py Feature Highlights: * Automatically find/download/install/upgrade dependencies at build time using the `EasyInstall tool `_, which supports downloading via HTTP, FTP, Subversion, and SourceForge, and automatically scans web pages linked from PyPI to find download links. (It's the closest thing to CPAN currently available for Python.) * Create `Python Eggs `_ - a single-file importable distribution format * Include data files inside your package directories, where your code can actually use them. (Python 2.4 distutils also supports this feature, but setuptools provides the feature for Python 2.3 packages also, and supports accessing data files in zipped packages too.) * Automatically include all packages in your source tree, without listing them individually in setup.py * Automatically include all relevant files in your source distributions, without needing to create a ``MANIFEST.in`` file, and without having to force regeneration of the ``MANIFEST`` file when your source tree changes. * Transparent Pyrex support, so that your setup.py can list ``.pyx`` files and still work even when the end-user doesn't have Pyrex installed (as long as you include the Pyrex-generated C in your source distribution) * Command aliases - create project-specific, per-user, or site-wide shortcut names for commonly used commands and options * PyPI upload support - upload your source distributions and eggs to PyPI * Deploy your project in "development mode", such that it's available on ``sys.path``, yet can still be edited directly from its source checkout. .. contents:: **Table of Contents** ----------------- Developer's Guide ----------------- Installing ``setuptools`` ========================= Download `ez_setup.py`_ and run it; this will download and install the appropriate egg for your Python version. .. _ez_setup.py: `bootstrap module`_ You may receive a message telling you about an obsolete version of setuptools being present; if so, you must be sure to delete it entirely, along with the old ``pkg_resources`` module if it's present on ``sys.path``. To get the in-development version of setuptools, run:: cvs -d:pserver:anonymous@cvs.sourceforge.net:/cvsroot/python login cvs -z3 -d:pserver:anonymous@cvs.sourceforge.net:/cvsroot/python \ co -d setuptools python/nondist/sandbox/setuptools You can then install it using the usual "setup.py install" incantation. Basic Use ========= For basic use of setuptools, just import things from setuptools instead of the distutils. Here's a minimal setup script using setuptools:: from setuptools import setup, find_packages setup( name = "HelloWorld", version = "0.1", packages = find_packages(), ) As you can see, it doesn't take much to use setuptools in a project. Just by doing the above, this project will be able to produce eggs, upload to PyPI, and automatically include all packages in the directory where the setup.py lives. See the `Command Reference`_ section below to see what commands you can give to this setup script. Of course, before you release your project to PyPI, you'll want to add a bit more information to your setup script to help people find or learn about your project. And maybe your project will have grown by then to include a few dependencies, and perhaps some data files and scripts:: from setuptools import setup, find_packages setup( name = "HelloWorld", version = "0.1", packages = find_packages(), scripts = ['say_hello.py'], # Project uses reStructuredText, so ensure that the docutils get # installed or upgraded on the target machine install_requires = ['docutils>=0.3'], package_data = { # If any package contains *.txt or *.rst files, include them: '': ['*.txt', '*.rst'], # And include any *.msg files found in the 'hello' package, too: 'hello': ['*.msg'], } # metadata for upload to PyPI author = "Me", author_email = "me@example.com", description = "This is an Example Package", license = "PSF", keywords = "hello world example examples", url = "http://example.com/HelloWorld/", # project home page, if any # could also include long_description, download_url, classifiers, etc. ) In the sections that follow, we'll explain what most of these ``setup()`` arguments do (except for the metadata ones), and the various ways you might use them in your own project(s). New and Changed ``setup()`` Keywords ==================================== The following keyword arguments to ``setup()`` are added or changed by ``setuptools``. All of them are optional; you do not have to supply them unless you need the associated ``setuptools`` feature. ``package_data`` A dictionary mapping package names to lists of glob patterns. For a complete description and examples, see the section below on `Including Data Files`_. ``zip_safe`` A boolean (True or False) flag specifying whether the project can be safely installed and run from a zip file. If this argument is not supplied, the ``bdist_egg`` command will have to analyze all of your project's contents for possible problems each time it buids an egg. ``install_requires`` A string or list of strings specifying what other distributions need to be installed when this one is. See the section below on `Declaring Dependencies`_ for details and examples of the format of this argument. ``entry_points`` A dictionary mapping entry point group names to strings or lists of strings defining the entry points. Entry points are used to support dynamic discovery of services or plugins provided by a project. See `Dynamic Discovery of Services and Plugins`_ for details and examples of the format of this argument. ``extras_require`` A dictionary mapping names of "extras" (optional features of your project) to strings or lists of strings specifying what other distributions must be installed to support those features. See the section below on `Declaring Dependencies`_ for details and examples of the format of this argument. ``namespace_packages`` A list of strings naming the project's "namespace packages". A namespace package is a package that may be split across multiple project distributions. For example, Zope 3's ``zope`` package is a namespace package, because subpackages like ``zope.interface`` and ``zope.publisher`` may be distributed separately. The egg runtime system can automatically merge such subpackages into a single parent package at runtime, as long as you declare them in each project that contains any subpackages of the namespace package, and as long as the namespace package's ``__init__.py`` does not contain any code. See the section below on `Namespace Packages`_ for more information. ``test_suite`` A string naming a ``unittest.TestCase`` subclass (or a module containing one or more of them, or a method of such a subclass), or naming a function that can be called with no arguments and returns a ``unittest.TestSuite``. Specifying this argument enables use of the `test`_ command to run the specified test suite, e.g. via ``setup.py test``. See the section on the `test`_ command below for more details. ``eager_resources`` A list of strings naming resources that should be extracted together, if any of them is needed, or if any C extensions included in the project are imported. This argument is only useful if the project will be installed as a zipfile, and there is a need to have all of the listed resources be extracted to the filesystem *as a unit*. Resources listed here should be '/'-separated paths, relative to the source root, so to list a resource ``foo.png`` in package ``bar.baz``, you would include the string ``bar/baz/foo.png`` in this argument. If you only need to obtain resources one at a time, or you don't have any C extensions that access other files in the project (such as data files or shared libraries), you probably do NOT need this argument and shouldn't mess with it. For more details on how this argument works, see the section below on `Automatic Resource Extraction`_. Using ``find_packages()`` ------------------------- For simple projects, it's usually easy enough to manually add packages to the ``packages`` argument of ``setup()``. However, for very large projects (Twisted, PEAK, Zope, Chandler, etc.), it can be a big burden to keep the package list updated. That's what ``setuptools.find_packages()`` is for. ``find_packages()`` takes a source directory, and a list of package names or patterns to exclude. If omitted, the source directory defaults to the same directory as the setup script. Some projects use a ``src`` or ``lib`` directory as the root of their source tree, and those projects would of course use ``"src"`` or ``"lib"`` as the first argument to ``find_packages()``. (And such projects also need something like ``package_dir = {'':'src'}`` in their ``setup()`` arguments, but that's just a normal distutils thing.) Anyway, ``find_packages()`` walks the target directory, and finds Python packages by looking for ``__init__.py`` files. It then filters the list of packages using the exclusion patterns. Exclusion patterns are package names, optionally including wildcards. For example, ``find_packages(exclude=["*.tests"])`` will exclude all packages whose last name part is ``tests``. Or, ``find_packages(exclude=["*.tests", "*.tests.*"])`` will also exclude any subpackages of packages named ``tests``, but it still won't exclude a top-level ``tests`` package or the children thereof. In fact, if you really want no ``tests`` packages at all, you'll need something like this:: find_packages(exclude=["*.tests", "*.tests.*", "tests.*", "tests"]) in order to cover all the bases. Really, the exclusion patterns are intended to cover simpler use cases than this, like excluding a single, specified package and its subpackages. Regardless of the target directory or exclusions, the ``find_packages()`` function returns a list of package names suitable for use as the ``packages`` argument to ``setup()``, and so is usually the easiest way to set that argument in your setup script. Especially since it frees you from having to remember to modify your setup script whenever your project grows additional top-level packages or subpackages. Declaring Dependencies ====================== ``setuptools`` supports automatically installing dependencies when a package is installed, and including information about dependencies in Python Eggs (so that package management tools like EasyInstall can use the information). ``setuptools`` and ``pkg_resources`` use a common syntax for specifying a project's required dependencies. This syntax consists of a project's PyPI name, optionally followed by a comma-separated list of "extras" in square brackets, optionally followed by a comma-separated list of version specifiers. A version specifier is one of the operators ``<``, ``>``, ``<=``, ``>=``, ``==`` or ``!=``, followed by a version identifier. Tokens may be separated by whitespace, but any whitespace or nonstandard characters within a project name or version identifier must be replaced with ``-``. Here are some example requirement specifiers:: docutils >= 0.3 # comment lines and \ continuations are allowed in requirement strings BazSpam ==1.1, ==1.2, ==1.3, ==1.4, ==1.5, \ ==1.6, ==1.7 # and so are line-end comments PEAK[FastCGI, reST]>=0.5a4 setuptools==0.5a7 The simplest way to include requirement specifiers is to use the ``install_requires`` argument to ``setup()``. It takes a string or list of strings containing requirement specifiers. If you include more than one requirement in a string, each requirement must begin on a new line. This has three effects: 1. When your project is installed, either by using EasyInstall, ``setup.py install``, or ``setup.py develop``, all of the dependencies not already installed will be located (via PyPI), downloaded, built (if necessary), and installed. 2. Any scripts in your project will be installed with wrappers that verify the availability of the specified dependencies at runtime, and ensure that the correct versions are added to ``sys.path`` (e.g. if multiple versions have been installed). 3. Python Egg distributions will include a metadata file listing the dependencies. Note, by the way, that if you declare your dependencies in ``setup.py``, you do *not* need to use the ``require()`` function in your scripts or modules, as long as you either install the project or use ``setup.py develop`` to do development work on it. (See `"Development Mode"`_ below for more details on using ``setup.py develop``.) Declaring "Extras" (optional features with their own dependencies) ------------------------------------------------------------------ Sometimes a project has "recommended" dependencies, that are not required for all uses of the project. For example, a project might offer optional PDF output if ReportLab is installed, and reStructuredText support if docutils is installed. These optional features are called "extras", and setuptools allows you to define their requirements as well. In this way, other projects that require these optional features can force the additional requirements to be installed, by naming the desired extras in their ``install_requires``. For example, let's say that Project A offers optional PDF and reST support:: setup( name="Project-A", ... extras_require = { 'PDF': ["ReportLab>=1.2", "RXP"], 'reST': ["docutils>=0.3"], } ) And that project B needs project A, *with* PDF support:: setup( name="Project-B", install_requires = ["Project-A[PDF]"], ... ) This will cause ReportLab to be installed along with project A, if project B is installed -- even if project A was already installed. In this way, a project can encapsulate groups of optional "downstream dependencies" under a feature name, so that packages that depend on it don't have to know what the downstream dependencies are. If a later version of Project A builds in PDF support and no longer needs ReportLab, or if it ends up needing other dependencies besides ReportLab in order to provide PDF support, Project B's setup information does not need to change, but the right packages will still be installed if needed. As you can see, the ``extras_require`` argument takes a dictionary mapping names of "extra" features, to strings or lists of strings describing those features' requirements. These requirements will *not* be automatically installed unless another package depends on them (directly or indirectly) by including the desired "extras" in square brackets after the associated project name. (Or if the extras were listed in a requirement spec on the EasyInstall command line.) Note, by the way, that if a project ends up not needing any other packages to support a feature, it should keep an empty requirements list for that feature in its ``extras_require`` argument, so that packages depending on that feature don't break (due to an invalid feature name). For example, if Project A above builds in PDF support and no longer needs ReportLab, it should change its setup to this:: setup( name="Project-A", ... extras_require = { 'PDF': [], 'reST': ["docutils>=0.3"], } ) so that Package B doesn't have to remove the ``[PDF]`` from its requirement specifier. Including Data Files ==================== The distutils have traditionally allowed installation of "data files", which are placed in a platform-specific location. However, the most common use case for data files distributed with a package is for use *by* the package, usually by including the data files in the package directory. Setuptools supports this by allowing a ``package_data`` argument to ``setup()``, e.g.:: from setuptools import setup, find_packages setup( ... package_data = { # If any package contains *.txt or *.rst files, include them: '': ['*.txt', '*.rst'], # And include any *.msg files found in the 'hello' package, too: 'hello': ['*.msg'], } ) The ``package_data`` argument is a dictionary that maps from package names to lists of glob patterns. The globs may include subdirectory names, if the data files are contained in a subdirectory of the package. For example, if the package tree looks like this:: setup.py src/ mypkg/ __init__.py mypkg.txt data/ somefile.dat otherdata.dat The setuptools setup file might look like this:: from setuptools import setup, find_packages setup( ... packages = find_packages('src'), # include all packages under src package_dir = {'':'src'}, # tell distutils packages are under src package_data = { # If any package contains *.txt files, include them: '': ['*.txt'], # And include any *.dat files found in the 'data' subdirectory # of the 'mypkg' package, also: 'mypkg': ['data/*.dat'], } ) Notice that if you list patterns in ``package_data`` under the empty string, these patterns are used to find files in every package, even ones that also have their own patterns listed. Thus, in the above example, the ``mypkg.txt`` file gets included even though it's not listed in the patterns for ``mypkg``. Also notice that if you use paths, you *must* use a forward slash (``/``) as the path separator, even if you are on Windows. Setuptools automatically converts slashes to appropriate platform-specific separators at build time. (Note: although the ``package_data`` argument was previously only available in ``setuptools``, it was also added to the Python ``distutils`` package as of Python 2.4; there is `some documentation for the feature`__ available on the python.org website.) __ http://docs.python.org/dist/node11.html Accessing Data Files at Runtime ------------------------------- Typically, existing programs manipulate a package's ``__file__`` attribute in order to find the location of data files. However, this manipulation isn't compatible with PEP 302-based import hooks, including importing from zip files and Python Eggs. It is strongly recommended that, if you are using data files, you should use the `Resource Management API`_ of ``pkg_resources`` to access them. The ``pkg_resources`` module is distributed as part of setuptools, so if you're using setuptools to distribute your package, there is no reason not to use its resource management API. See also `Accessing Package Resources`_ for a quick example of converting code that uses ``__file__`` to use ``pkg_resources`` instead. .. _Resource Management API: http://peak.telecommunity.com/DevCenter/PythonEggs#resource-management .. _Accessing Package Resources: http://peak.telecommunity.com/DevCenter/PythonEggs#accessing-package-resources Non-Package Data Files ---------------------- The ``distutils`` normally install general "data files" to a platform-specific location (e.g. ``/usr/share``). This feature intended to be used for things like documentation, example configuration files, and the like. ``setuptools`` does not install these data files in a separate location, however. They are bundled inside the egg file or directory, alongside the Python modules and packages. The data files can also be accessed using the `Resource Management API`_, by specifying a ``Requirement`` instead of a package name:: from pkg_resources import Requirement, resource_filename filename = resource_filename(Requirement.parse("MyProject"),"sample.conf") The above code will obtain the filename of the "sample.conf" file in the data root of the "MyProject" distribution. Note, by the way, that this encapsulation of data files means that you can't actually install data files to some arbitrary location on a user's machine; this is a feature, not a bug. You can always include a script in your distribution that extracts and copies your the documentation or data files to a user-specified location, at their discretion. If you put related data files in a single directory, you can use ``resource_filename()`` with the directory name to get a filesystem directory that then can be copied with the ``shutil`` module. (Even if your package is installed as a zipfile, calling ``resource_filename()`` on a directory will return an actual filesystem directory, whose contents will be that entire subtree of your distribution.) (Of course, if you're writing a new package, you can just as easily place your data files or directories inside one of your packages, rather than using the distutils' approach. However, if you're updating an existing application, it may be simpler not to change the way it currently specifies these data files.) Automatic Resource Extraction ----------------------------- If you are using tools that expect your resources to be "real" files, or your project includes non-extension native libraries or other files that your C extensions expect to be able to access, you may need to list those files in the ``eager_resources`` argument to ``setup()``, so that the files will be extracted together, whenever a C extension in the project is imported. This is especially important if your project includes shared libraries *other* than distutils-built C extensions. Those shared libraries should be listed as ``eager_resources``, because they need to be present in the filesystem when the C extensions that link to them are used. The ``pkg_resources`` runtime for compressed packages will automatically extract *all* C extensions and ``eager_resources`` at the same time, whenever *any* C extension or eager resource is requested via the ``resource_filename()`` API. (C extensions are imported using ``resource_filename()`` internally.) This ensures that C extensions will see all of the "real" files that they expect to see. Note also that you can list directory resource names in ``eager_resources`` as well, in which case the directory's contents (including subdirectories) will be extracted whenever any C extension or eager resource is requested. Please note that if you're not sure whether you need to use this argument, you don't! It's really intended to support projects with lots of non-Python dependencies and as a last resort for crufty projects that can't otherwise handle being compressed. If your package is pure Python, Python plus data files, or Python plus C, you really don't need this. You've got to be using either C or an external program that needs "real" files in your project before there's any possibility of ``eager_resources`` being relevant to your project. Extensible Applications and Frameworks ====================================== Dynamic Discovery of Services and Plugins ----------------------------------------- ``setuptools`` supports creating libraries that "plug in" to extensible applications and frameworks, by letting you register "entry points" in your project that can be imported by the application or framework. For example, suppose that a blogging tool wants to support plugins that provide translation for various file types to the blog's output format. The framework might define an "entry point group" called ``blogtool.parsers``, and then allow plugins to register entry points for the file extensions they support. This would allow people to create distributions that contain one or more parsers for different file types, and then the blogging tool would be able to find the parsers at runtime by looking up an entry point for the file extension (or mime type, or however it wants to). Note that if the blogging tool includes parsers for certain file formats, it can register these as entry points in its own setup script, which means it doesn't have to special-case its built-in formats. They can just be treated the same as any other plugin's entry points would be. If you're creating a project that plugs in to an existing application or framework, you'll need to know what entry points or entry point groups are defined by that application or framework. Then, you can register entry points in your setup script. Here are a few examples of ways you might register an ``.rst`` file parser entry point in the ``blogtool.parsers`` entry point group, for our hypothetical blogging tool:: setup( # ... entry_points = {'blogtool.parsers': '.rst = some_module:SomeClass'} ) setup( # ... entry_points = {'blogtool.parsers': ['.rst = some_module:a_func']} ) setup( # ... entry_points = """ [blogtool.parsers] .rst = some.nested.module:SomeClass.some_classmethod [reST] """, extras_require = dict(reST = "Docutils>=0.3.5") ) The ``entry_points`` argument to ``setup()`` accepts either a string with ``.ini``-style sections, or a dictionary mapping entry point group names to either strings or lists of strings containing entry point specifiers. An entry point specifier consists of a name and value, separated by an ``=`` sign. The value consists of a dotted module name, optionally followed by a ``:`` and a dotted identifier naming an object within the module. It can also include a bracketed list of "extras" that are required for the entry point to be used. When the invoking application or framework requests loading of an entry point, any requirements implied by the associated extras will be passed to ``pkg_resources.require()``, so that an appropriate error message can be displayed if the needed package(s) are missing. (Of course, the invoking app or framework can ignore such errors if it wants to make an entry point optional if a requirement isn't installed.) "Development Mode" ================== Under normal circumstances, the ``distutils`` assume that you are going to build a distribution of your project, not use it in its "raw" or "unbuilt" form. If you were to use the ``distutils`` that way, you would have to rebuild and reinstall your project every time you made a change to it during development. Another problem that sometimes comes up with the ``distutils`` is that you may need to do development on two related projects at the same time. You may need to put both projects' packages in the same directory to run them, but need to keep them separate for revision control purposes. How can you do this? Setuptools allows you to deploy your projects for use in a common directory or staging area, but without copying any files. Thus, you can edit each project's code in its checkout directory, and only need to run build commands when you change a project's C extensions or similarly compiled files. You can even deploy a project into another project's checkout directory, if that's your preferred way of working (as opposed to using a common independent staging area or the site-packages directory). To do this, use the ``setup.py develop`` command. It works very similarly to ``setup.py install`` or the EasyInstall tool, except that it doesn't actually install anything. Instead, it creates a special ``.egg-link`` file in the deployment directory, that links to your project's source code. And, if your deployment directory is Python's ``site-packages`` directory, it will also update the ``easy-install.pth`` file to include your project's source code, thereby making it available on ``sys.path`` for all programs using that Python installation. In addition, the ``develop`` command creates wrapper scripts in the target script directory that will run your in-development scripts after ensuring that all your ``install_requires`` packages are available on ``sys.path``. You can deploy the same project to multiple staging areas, e.g. if you have multiple projects on the same machine that are sharing the same project you're doing development work. When you're done with a given development task, you can remove the project source from a staging area using ``setup.py develop --uninstall``, specifying the desired staging area if it's not the default. There are several options to control the precise behavior of the ``develop`` command; see the section on the `develop`_ command below for more details. Distributing a ``setuptools``-based package =========================================== Using ``setuptools``... Without bundling it! --------------------------------------------- Your users might not have ``setuptools`` installed on their machines, or even if they do, it might not be the right version. Fixing this is easy; just download `ez_setup.py`_, and put it in the same directory as your ``setup.py`` script. (Be sure to add it to your revision control system, too.) Then add these two lines to the very top of your setup script, before the script imports anything from setuptools:: import ez_setup ez_setup.use_setuptools() That's it. The ``ez_setup`` module will automatically download a matching version of ``setuptools`` from PyPI, if it isn't present on the target system. Whenever you install an updated version of setuptools, you should also update your projects' ``ez_setup.py`` files, so that a matching version gets installed on the target machine(s). By the way, setuptools supports the new PyPI "upload" command, so you can use ``setup.py sdist upload`` or ``setup.py bdist_egg upload`` to upload your source or egg distributions respectively. Your project's current version must be registered with PyPI first, of course; you can use ``setup.py register`` to do that. Or you can do it all in one step, e.g. ``setup.py register sdist bdist_egg upload`` will register the package, build source and egg distributions, and then upload them both to PyPI, where they'll be easily found by other projects that depend on them. Managing Multiple Projects -------------------------- If you're managing several projects that need to use ``ez_setup``, and you are using Subversion as your revision control system, you can use the "svn:externals" property to share a single copy of ``ez_setup`` between projects, so that it will always be up-to-date whenever you check out or update an individual project, without having to manually update each project to use a new version. However, because Subversion only supports using directories as externals, you have to turn ``ez_setup.py`` into ``ez_setup/__init__.py`` in order to do this, then create "externals" definitions that map the ``ez_setup`` directory into each project. Also, if any of your projects use ``find_packages()`` on their setup directory, you will need to exclude the resulting ``ez_setup`` package, to keep it from being included in your distributions, e.g.:: setup( ... packages = find_packages(exclude=['ez_setup']), ) Of course, the ``ez_setup`` package will still be included in your packages' source distributions, as it needs to be. For your convenience, you may use the following external definition, which will track the latest version of setuptools:: ez_setup svn://svn.eby-sarna.com/svnroot/ez_setup You can set this by executing this command in your project directory:: svn propedit svn:externals . And then adding the line shown above to the file that comes up for editing. Setting the ``zip_safe`` flag ----------------------------- For maximum performance, Python packages are best installed as zip files. Not all packages, however, are capable of running in compressed form, because they may expect to be able to access either source code or data files as normal operating system files. So, ``setuptools`` can install your project as a zipfile or a directory, and its default choice is determined by the project's ``zip_safe`` flag. You can pass a True or False value for the ``zip_safe`` argument to the ``setup()`` function, or you can omit it. If you omit it, the ``bdist_egg`` command will analyze your project's contents to see if it can detect any conditions that would prevent it from working in a zipfile. It will output notices to the console about any such conditions that it finds. Currently, this analysis is extremely conservative: it will consider the project unsafe if it contains any C extensions or datafiles whatsoever. This does *not* mean that the project can't or won't work as a zipfile! It just means that the ``bdist_egg`` authors aren't yet comfortable asserting that the project *will* work. If the project contains no C or data files, and does no ``__file__`` or ``__path__`` introspection or source code manipulation, then there is an extremely solid chance the project will work when installed as a zipfile. (And if the project uses ``pkg_resources`` for all its data file access, then C extensions and other data files shouldn't be a problem at all. See the `Accessing Data Files at Runtime`_ section above for more information.) However, if ``bdist_egg`` can't be *sure* that your package will work, but you've checked over all the warnings it issued, and you are either satisfied it *will* work (or if you want to try it for yourself), then you should set ``zip_safe`` to ``True`` in your ``setup()`` call. If it turns out that it doesn't work, you can always change it to ``False``, which will force ``setuptools`` to install your project as a directory rather than as a zipfile. Of course, the end-user can still override either decision, if they are using EasyInstall to install your package. And, if you want to override for testing purposes, you can just run ``setup.py easy_install --zip-ok .`` or ``setup.py easy_install --always-unzip .`` in your project directory. to install the package as a zipfile or directory, respectively. In the future, as we gain more experience with different packages and become more satisfied with the robustness of the ``pkg_resources`` runtime, the "zip safety" analysis may become less conservative. However, we strongly recommend that you determine for yourself whether your project functions correctly when installed as a zipfile, correct any problems if you can, and then make an explicit declaration of ``True`` or ``False`` for the ``zip_safe`` flag, so that it will not be necessary for ``bdist_egg`` or ``EasyInstall`` to try to guess whether your project can work as a zipfile. Namespace Packages ------------------ Sometimes, a large package is more useful if distributed as a collection of smaller eggs. However, Python does not normally allow the contents of a package to be retrieved from more than one location. "Namespace packages" are a solution for this problem. When you declare a package to be a namespace package, it means that the package has no meaningful contents in its ``__init__.py``, and that it is merely a container for modules and subpackages. The ``pkg_resources`` runtime will automatically ensure that the contents of namespace packages that are spread over multiple eggs or directories are combined into a single virtual package. The ``namespace_packages`` argument to ``setup()`` lets you declare your project's namespace packages, so that they will be included in your project's metadata. Then, the runtime will automatically detect this when it adds the distribution to ``sys.path``, and ensure that the packages are properly merged. The argument should list the namespace packages that the egg participates in. For example, the ZopeInterface project might do this:: setup( # ... namespace_packages = ['zope'] ) because it contains a ``zope.interface`` package that lives in the ``zope`` namespace package. Similarly, a project for a standalone ``zope.publisher`` would also declare the ``zope`` namespace package. Namespace packages don't have to be top-level packages. For example, Zope 3's ``zope.app`` package is a namespace package, and in the future PEAK's ``peak.util`` package will be too. Note, by the way, that your project's source tree must include the namespace packages' ``__init__.py`` files (and the ``__init__.py`` of any parent packages), in a normal Python package layout. These ``__init__.py`` files should not contain any code or data, because only *one* egg's ``__init__.py`` files will be used to construct the parent packages in memory at runtime, and there is no guarantee which egg will be used. For example, if both ``zope.interface`` and ``zope.publisher`` have been installed from separate distributions, it is unspecified which of the two distributions' ``zope/__init__.py`` files will be used to create the ``zope`` package in memory. Therefore, it is better not to have any code or data in a namespace package's ``__init__`` module, so as to prevent any complications. (This is one reason the concept is called a "namespace package": it is a package that exists *only* to provide a namespace under which other modules or packages are gathered. In Java, for example, namespace packages are often used just to avoid naming collisions between different projects, using package names like ``org.apache`` as a namespace for packages that are part of apache.org projects.) Tagging and "Daily Build" or "Snapshot" Releases ------------------------------------------------ When a set of related projects are under development, it may be important to track finer-grained version increments than you would normally use for e.g. "stable" releases. While stable releases might be measured in dotted numbers with alpha/beta/etc. status codes, development versions of a project often need to be tracked by revision or build number or even build date. This is especially true when projects in development need to refer to one another, and therefore may literally need an up-to-the-minute version of something! To support these scenarios, ``setuptools`` allows you to "tag" your source and egg distributions by adding one or more of the following to the project's "official" version identifier: * An identifying string, such as "build" or "dev", or a manually-tracked build or revision number (``--tag-build=STRING, -bSTRING``) * A "last-modified revision number" string generated automatically from Subversion's metadata (assuming your project is being built from a Subversion "working copy") (``--tag-svn-revision, -r``) * An 8-character representation of the build date (``--tag-date, -d``) You can add these tags by adding ``egg_info`` and the desired options to the command line ahead of the ``sdist`` or ``bdist`` commands that you want to generate a daily build or snapshot for. See the section below on the `egg_info`_ command for more details. Also, if you are creating builds frequently, and either building them in a downloadable location or are copying them to a distribution server, you should probably also check out the `rotate`_ command, which lets you automatically delete all but the N most-recently-modified distributions matching a glob pattern. So, you can use a command line like:: setup.py egg_info -rbDEV bdist_egg rotate -m.egg -k3 to build an egg whose version info includes 'DEV-rNNNN' (where NNNN is the most recent Subversion revision that affected the source tree), and then delete any egg files from the distribution directory except for the three that were built most recently. If you have to manage automated builds for multiple packages, each with different tagging and rotation policies, you may also want to check out the `alias`_ command, which would let each package define an alias like ``daily`` that would perform the necessary tag, build, and rotate commands. Then, a simpler script or cron job could just run ``setup.py daily`` in each project directory. (And, you could also define sitewide or per-user default versions of the ``daily`` alias, so that projects that didn't define their own would use the appropriate defaults.) Generating Source Distributions ------------------------------- ``setuptools`` enhances the distutils' default algorithm for source file selection, so that all files managed by CVS or Subversion in your project tree are included in any source distribution you build. This is a big improvement over having to manually write a ``MANIFEST.in`` file and try to keep it in sync with your project. So, if you are using CVS or Subversion, and your source distributions only need to include files that you're tracking in revision control, don't create a a ``MANIFEST.in`` file for your project. (And, if you already have one, you might consider deleting it the next time you would otherwise have to change it.) Unlike the distutils, ``setuptools`` regenerates the source distribution ``MANIFEST`` file every time you build a source distribution, as long as you *don't* have a ``MANIFEST.in`` file. If you do have a ``MANIFEST.in`` (e.g. because you aren't using CVS or Subversion), then you'll have to follow the normal distutils procedures for managing what files get included in a source distribution, and setuptools' enhanced algorithms will *not* be used. (Note, by the way, that if you're using some other revision control system, you might consider submitting a patch to the ``setuptools.command.sdist`` module so we can include support for it, too.) Making your package available for EasyInstall --------------------------------------------- If you use the ``register`` command (``setup.py register``) to register your package with PyPI, that's most of the battle right there. (See the `docs for the register command`_ for more details.) .. _docs for the register command: http://docs.python.org/dist/package-index.html If you also use the `upload`_ command to upload actual distributions of your package, that's even better, because EasyInstall will be able to find and download them directly from your project's PyPI page. However, there may be reasons why you don't want to upload distributions to PyPI, and just want your existing distributions (or perhaps a Subversion checkout) to be used instead. So here's what you need to do before running the ``register`` command. There are three ``setup()`` arguments that affect EasyInstall: ``url`` and ``download_url`` These become links on your project's PyPI page. EasyInstall will examine them to see if they link to a package ("primary links"), or whether they are HTML pages. If they're HTML pages, EasyInstall scans all HREF's on the page for primary links ``long_description`` EasyInstall will check any URLs contained in this argument to see if they are primary links. A URL is considered a "primary link" if it is a link to a .tar.gz, .tgz, .zip, .egg, .egg.zip, .tar.bz2, or .exe file, or if it has an ``#egg=project`` or ``#egg=project-version`` fragment identifier attached to it. EasyInstall attempts to determine a project name and optional version number from the text of a primary link *without* downloading it. When it has found all the primary links, EasyInstall will select the best match based on requested version, platform compatibility, and other criteria. So, if your ``url`` or ``download_url`` point either directly to a downloadable source distribution, or to HTML page(s) that have direct links to such, then EasyInstall will be able to locate downloads automatically. If you want to make Subversion checkouts available, then you should create links with either ``#egg=project`` or ``#egg=project-version`` added to the URL (replacing ``project`` and ``version`` with appropriate values). Note that Subversion checkout links are of lower precedence than other kinds of distributions, so EasyInstall will not select a Subversion checkout for downloading unless it has a version included in the ``#egg=`` suffix, and it's a higher version than EasyInstall has seen in any other links for your project. As a result, it's a common practice to use mark checkout URLs with a version of "dev" (i.e., ``#egg=projectname-dev``), so that users can do something like this:: easy_install --editable projectname==dev in order to check out the in-development version of ``projectname``. Distributing Extensions compiled with Pyrex ------------------------------------------- ``setuptools`` includes transparent support for building Pyrex extensions, as long as you define your extensions using ``setuptools.Extension``, *not* ``distutils.Extension``. You must also not import anything from Pyrex in your setup script. If you follow these rules, you can safely list ``.pyx`` files as the source of your ``Extension`` objects in the setup script. ``setuptools`` will detect at build time whether Pyrex is installed or not. If it is, then ``setuptools`` will use it. If not, then ``setuptools`` will silently change the ``Extension`` objects to refer to the ``.c`` counterparts of the ``.pyx`` files, so that the normal distutils C compilation process will occur. Of course, for this to work, your source distributions must include the C code generated by Pyrex, as well as your original ``.pyx`` files. This means that you will probably want to include current ``.c`` files in your revision control system, rebuilding them whenever you check changes in for the ``.pyx`` source files. This will ensure that people tracking your project in CVS or Subversion will be able to build it even if they don't have Pyrex installed, and that your source releases will be similarly usable with or without Pyrex. ----------------- Command Reference ----------------- .. _alias: ``alias`` - Define shortcuts for commonly used commands ======================================================= Sometimes, you need to use the same commands over and over, but you can't necessarily set them as defaults. For example, if you produce both development snapshot releases and "stable" releases of a project, you may want to put the distributions in different places, or use different ``egg_info`` tagging options, etc. In these cases, it doesn't make sense to set the options in a distutils configuration file, because the values of the options changed based on what you're trying to do. Setuptools therefore allows you to define "aliases" - shortcut names for an arbitrary string of commands and options, using ``setup.py alias aliasname expansion``, where aliasname is the name of the new alias, and the remainder of the command line supplies its expansion. For example, this command defines a sitewide alias called "daily", that sets various ``egg_info`` tagging options:: setup.py alias --global-config daily egg_info --tag-svn-revision \ --tag-build=development Once the alias is defined, it can then be used with other setup commands, e.g.:: setup.py daily bdist_egg # generate a daily-build .egg file setup.py daily sdist # generate a daily-build source distro setup.py daily sdist bdist_egg # generate both The above commands are interpreted as if the word ``daily`` were replaced with ``egg_info --tag-svn-revision --tag-build=development``. Note that setuptools will expand each alias *at most once* in a given command line. This serves two purposes. First, if you accidentally create an alias loop, it will have no effect; you'll instead get an error message about an unknown command. Second, it allows you to define an alias for a command, that uses that command. For example, this (project-local) alias:: setup.py alias bdist_egg bdist_egg rotate -k1 -m.egg redefines the ``bdist_egg`` command so that it always runs the ``rotate`` command afterwards to delete all but the newest egg file. It doesn't loop indefinitely on ``bdist_egg`` because the alias is only expanded once when used. You can remove a defined alias with the ``--remove`` (or ``-r``) option, e.g.:: setup.py alias --global-config --remove daily would delete the "daily" alias we defined above. Aliases can be defined on a project-specific, per-user, or sitewide basis. The default is to define or remove a project-specific alias, but you can use any of the `configuration file options`_ (listed under the `saveopts`_ command, below) to determine which distutils configuration file an aliases will be added to (or removed from). Note that if you omit the "expansion" argument to the ``alias`` command, you'll get output showing that alias' current definition (and what configuration file it's defined in). If you omit the alias name as well, you'll get a listing of all current aliases along with their configuration file locations. ``bdist_egg`` - Create a Python Egg for the project =================================================== This command generates a Python Egg (``.egg`` file) for the project. Python Eggs are the preferred binary distribution format for EasyInstall, because they are cross-platform (for "pure" packages), directly importable, and contain project metadata including scripts and information about the project's dependencies. They can be simply downloaded and added to ``sys.path`` directly, or they can be placed in a directory on ``sys.path`` and then automatically discovered by the egg runtime system. This command runs the `egg_info`_ command (if it hasn't already run) to update the project's metadata (``.egg-info``) directory. If you have added any extra metadata files to the ``.egg-info`` directory, those files will be included in the new egg file's metadata directory, for use by the egg runtime system or by any applications or frameworks that use that metadata. You won't usually need to specify any special options for this command; just use ``bdist_egg`` and you're done. But there are a few options that may be occasionally useful: ``--dist-dir=DIR, -d DIR`` Set the directory where the ``.egg`` file will be placed. If you don't supply this, then the ``--dist-dir`` setting of the ``bdist`` command will be used, which is usually a directory named ``dist`` in the project directory. ``--plat-name=PLATFORM, -p PLATFORM`` Set the platform name string that will be embedded in the egg's filename (assuming the egg contains C extensions). This can be used to override the distutils default platform name with something more meaningful. Keep in mind, however, that the egg runtime system expects to see eggs with distutils platform names, so it may ignore or reject eggs with non-standard platform names. Similarly, the EasyInstall program may ignore them when searching web pages for download links. However, if you are cross-compiling or doing some other unusual things, you might find a use for this option. ``--exclude-source-files`` Don't include any modules' ``.py`` files in the egg, just compiled Python, C, and data files. (Note that this doesn't affect any ``.py`` files in the EGG-INFO directory or its subdirectories, since for example there may be scripts with a ``.py`` extension which must still be retained.) We don't recommend that you use this option except for packages that are being bundled for proprietary end-user applications, or for "embedded" scenarios where space is at an absolute premium. On the other hand, if your package is going to be installed and used in compressed form, you might as well exclude the source because Python's ``traceback`` module doesn't currently understand how to display zipped source code anyway, or how to deal with files that are in a different place from where their code was compiled. There are also some options you will probably never need, but which are there because they were copied from similar ``bdist`` commands used as an example for creating this one. They may be useful for testing and debugging, however, which is why we kept them: ``--keep-temp, -k`` Keep the contents of the ``--bdist-dir`` tree around after creating the ``.egg`` file. ``--bdist-dir=DIR, -b DIR`` Set the temporary directory for creating the distribution. The entire contents of this directory are zipped to create the ``.egg`` file, after running various installation commands to copy the package's modules, data, and extensions here. ``--skip-build`` Skip doing any "build" commands; just go straight to the install-and-compress phases. .. _develop: ``develop`` - Deploy the project source in "Development Mode" ============================================================= This command allows you to deploy your project's source for use in one or more "staging areas" where it will be available for importing. This deployment is done in such a way that changes to the project source are immediately available in the staging area(s), without needing to run a build or install step after each change. The ``develop`` command works by creating an ``.egg-link`` file (named for the project) in the given staging area. If the staging area is Python's ``site-packages`` directory, it also updates an ``easy-install.pth`` file so that the project is on ``sys.path`` by default for all programs run using that Python installation. The ``develop`` command also installs wrapper scripts in the staging area (or a separate directory, as specified) that will ensure the project's dependencies are available on ``sys.path`` before running the project's source scripts. And, it ensures that any missing project dependencies are available in the staging area, by downloading and installing them if necessary. Last, but not least, the ``develop`` command invokes the ``build_ext -i`` command to ensure any C extensions in the project have been built and are up-to-date, and the ``egg_info`` command to ensure the project's metadata is updated (so that the runtime and wrappers know what the project's dependencies are). If you make any changes to the project's setup script or C extensions, you should rerun the ``develop`` command against all relevant staging areas to keep the project's scripts, metadata and extensions up-to-date. Most other kinds of changes to your project should not require any build operations or rerunning ``develop``, but keep in mind that even minor changes to the setup script (e.g. changing an entry point definition) require you to re-run the ``develop`` or ``test`` commands to keep the distribution updated. Here are the options that the ``develop`` command accepts. Note that they affect the project's dependencies as well as the project itself, so if you have dependencies that need to be installed and you use ``--exclude-scripts`` (for example), the dependencies' scripts will not be installed either! For this reason, you may want to use EasyInstall to install the project's dependencies before using the ``develop`` command, if you need finer control over the installation options for dependencies. ``--uninstall, -u`` Un-deploy the current project. You may use the ``--install-dir`` or ``-d`` option to designate the staging area. The created ``.egg-link`` file will be removed, if present and it is still pointing to the project directory. The project directory will be removed from ``easy-install.pth`` if the staging area is Python's ``site-packages`` directory. Note that this option currently does *not* uninstall script wrappers! You must uninstall them yourself, or overwrite them by using EasyInstall to activate a different version of the package. You can also avoid installing script wrappers in the first place, if you use the ``--exclude-scripts`` (aka ``-x``) option when you run ``develop`` to deploy the project. ``--multi-version, -m`` "Multi-version" mode. Specifying this option prevents ``develop`` from adding an ``easy-install.pth`` entry for the project(s) being deployed, and if an entry for any version of a project already exists, the entry will be removed upon successful deployment. In multi-version mode, no specific version of the package is available for importing, unless you use ``pkg_resources.require()`` to put it on ``sys.path``, or you are running a wrapper script generated by ``setuptools`` or EasyInstall. (In which case the wrapper script calls ``require()`` for you.) Note that if you install to a directory other than ``site-packages``, this option is automatically in effect, because ``.pth`` files can only be used in ``site-packages`` (at least in Python 2.3 and 2.4). So, if you use the ``--install-dir`` or ``-d`` option (or they are set via configuration file(s)) your project and its dependencies will be deployed in multi- version mode. ``--install-dir=DIR, -d DIR`` Set the installation directory (staging area). If this option is not directly specified on the command line or in a distutils configuration file, the distutils default installation location is used. Normally, this will be the ``site-packages`` directory, but if you are using distutils configuration files, setting things like ``prefix`` or ``install_lib``, then those settings are taken into account when computing the default staging area. ``--script-dir=DIR, -s DIR`` Set the script installation directory. If you don't supply this option (via the command line or a configuration file), but you *have* supplied an ``--install-dir`` (via command line or config file), then this option defaults to the same directory, so that the scripts will be able to find their associated package installation. Otherwise, this setting defaults to the location where the distutils would normally install scripts, taking any distutils configuration file settings into account. ``--exclude-scripts, -x`` Don't deploy script wrappers. This is useful if you don't want to disturb existing versions of the scripts in the staging area. ``--always-copy, -a`` Copy all needed distributions to the staging area, even if they are already present in another directory on ``sys.path``. By default, if a requirement can be met using a distribution that is already available in a directory on ``sys.path``, it will not be copied to the staging area. .. _egg_info: ``egg_info`` - Create egg metadata and set build tags ===================================================== This command performs two operations: it updates a project's ``.egg-info`` metadata directory (used by the ``bdist_egg``, ``develop``, and ``test`` commands), and it allows you to temporarily change a project's version string, to support "daily builds" or "snapshot" releases. It is run automatically by the ``sdist``, ``bdist_egg``, ``develop``, and ``test`` commands in order to update the project's metadata, but you can also specify it explicitly in order to temporarily change the project's version string. The following options can be used to modify the project's version string for all remaining commands on the setup command line. The options are processed in the order shown, so if you use more than one, the requested tags will be added in the following order: ``--tag-build=NAME, -b NAME`` Append NAME to the project's version string. Due to the way setuptools processes "pre-release" version suffixes beginning with the letters "a" through "e" (like "alpha", "beta", and "candidate"), you will usually want to use a tag like "build" or "dev", as this will cause the version number to be considered *lower* than the project's default version. (If you want to make the version number *higher* than the default version, you can always leave off --tag-build and use one or both of the following options.) ``--tag-svn-revision, -r`` If the current directory is a Subversion checkout (i.e. has a ``.svn`` subdirectory, this appends a string of the form "-rNNNN" to the project's version string, where NNNN is the revision number of the most recent modification to the current directory, as obtained from the ``svn info`` command. ``--tag-date, -d`` Add a date stamp of the form "-YYYYMMDD" (e.g. "-20050528") to the project's version number. For advanced uses, there is one other option that can be set, to change the location of the project's ``.egg-info`` directory. Commands that need to find the project's source directory or metadata should get it from this setting: ``--egg-base=SOURCEDIR, -e SOURCEDIR`` Specify the directory that should contain the .egg-info directory. This should normally be the root of your project's source tree (which is not necessarily the same as your project directory; some projects use a ``src`` or ``lib`` subdirectory as the source root). You should not normally need to specify this directory, as it is normally determined from the ``package_dir`` argument to the ``setup()`` function, if any. If there is no ``package_dir`` set, this option defaults to the current directory. .. _rotate: ``rotate`` - Delete outdated distribution files =============================================== As you develop new versions of your project, your distribution (``dist``) directory will gradually fill up with older source and/or binary distribution files. The ``rotate`` command lets you automatically clean these up, keeping only the N most-recently modified files matching a given pattern. ``--match=PATTERNLIST, -m PATTERNLIST`` Comma-separated list of glob patterns to match. This option is *required*. The project name and ``-*`` is prepended to the supplied patterns, in order to match only distributions belonging to the current project (in case you have a shared distribution directory for multiple projects). Typically, you will use a glob pattern like ``.zip`` or ``.egg`` to match files of the specified type. Note that each supplied pattern is treated as a distinct group of files for purposes of selecting files to delete. ``--keep=COUNT, -k COUNT`` Number of matching distributions to keep. For each group of files identified by a pattern specified with the ``--match`` option, delete all but the COUNT most-recently-modified files in that group. This option is *required*. ``--dist-dir=DIR, -d DIR`` Directory where the distributions are. This defaults to the value of the ``bdist`` command's ``--dist-dir`` option, which will usually be the project's ``dist`` subdirectory. **Example 1**: Delete all .tar.gz files from the distribution directory, except for the 3 most recently modified ones:: setup.py rotate --match=.tar.gz --keep=3 **Example 2**: Delete all Python 2.3 or Python 2.4 eggs from the distribution directory, except the most recently modified one for each Python version:: setup.py rotate --match=-py2.3*.egg,-py2.4*.egg --keep=1 .. _saveopts: ``saveopts`` - Save used options to a configuration file ======================================================== Finding and editing ``distutils`` configuration files can be a pain, especially since you also have to translate the configuration options from command-line form to the proper configuration file format. You can avoid these hassles by using the ``saveopts`` command. Just add it to the command line to save the options you used. For example, this command builds the project using the ``mingw32`` C compiler, then saves the --compiler setting as the default for future builds (even those run implicitly by the ``install`` command):: setup.py build --compiler=mingw32 saveopts The ``saveopts`` command saves all options for every commmand specified on the command line to the project's local ``setup.cfg`` file, unless you use one of the `configuration file options`_ to change where the options are saved. For example, this command does the same as above, but saves the compiler setting to the site-wide (global) distutils configuration:: setup.py build --compiler=mingw32 saveopts -g Note that it doesn't matter where you place the ``saveopts`` command on the command line; it will still save all the options specified for all commands. For example, this is another valid way to spell the last example:: setup.py saveopts -g build --compiler=mingw32 Note, however, that all of the commands specified are always run, regardless of where ``saveopts`` is placed on the command line. Configuration File Options -------------------------- Normally, settings such as options and aliases are saved to the project's local ``setup.cfg`` file. But you can override this and save them to the global or per-user configuration files, or to a manually-specified filename. ``--global-config, -g`` Save settings to the global ``distutils.cfg`` file inside the ``distutils`` package directory. You must have write access to that directory to use this option. You also can't combine this option with ``-u`` or ``-f``. ``--user-config, -u`` Save settings to the current user's ``~/.pydistutils.cfg`` (POSIX) or ``$HOME/pydistutils.cfg`` (Windows) file. You can't combine this option with ``-g`` or ``-f``. ``--filename=FILENAME, -f FILENAME`` Save settings to the specified configuration file to use. You can't combine this option with ``-g`` or ``-u``. Note that if you specify a non-standard filename, the ``distutils`` and ``setuptools`` will not use the file's contents. This option is mainly included for use in testing. These options are used by other ``setuptools`` commands that modify configuration files, such as the `alias`_ and `setopt`_ commands. .. _setopt: ``setopt`` - Set a distutils or setuptools option in a config file ================================================================== This command is mainly for use by scripts, but it can also be used as a quick and dirty way to change a distutils configuration option without having to remember what file the options are in and then open an editor. **Example 1**. Set the default C compiler to ``mingw32`` (using long option names):: setup.py setopt --command=build --option=compiler --set-value=mingw32 **Example 2**. Remove any setting for the distutils default package installation directory (short option names):: setup.py setopt -c install -o install_lib -r Options for the ``setopt`` command: ``--command=COMMAND, -c COMMAND`` Command to set the option for. This option is required. ``--option=OPTION, -o OPTION`` The name of the option to set. This option is required. ``--set-value=VALUE, -s VALUE`` The value to set the option to. Not needed if ``-r`` or ``--remove`` is set. ``--remove, -r`` Remove (unset) the option, instead of setting it. In addition to the above options, you may use any of the `configuration file options`_ (listed under the `saveopts`_ command, above) to determine which distutils configuration file the option will be added to (or removed from). .. _test: ``test`` - Build package and run a unittest suite ================================================= When doing test-driven development, or running automated builds that need testing before they are deployed for downloading or use, it's often useful to be able to run a project's unit tests without actually deploying the project anywhere, even using the ``develop`` command. The ``test`` command runs a project's unit tests without actually deploying it, by temporarily putting the project's source on ``sys.path``, after first running ``build_ext -i`` and ``egg_info`` to ensure that any C extensions and project metadata are up-to-date. To use this command, your project's tests must be wrapped in a ``unittest`` test suite by either a function, a ``TestCase`` class or method, or a module containing ``TestCase`` classes. Note that many test systems including ``doctest`` support wrapping their non-``unittest`` tests in ``TestSuite`` objects. So, if you are using a test package that does not support this, we suggest you encourage its developers to implement test suite support, as this is a convenient and standard way to aggregate a collection of tests to be run under a common test harness. By default, tests will be run in the "verbose" mode of the ``unittest`` package's text test runner, but you can get the "quiet" mode (just dots) if you supply the ``-q`` or ``--quiet`` option, either as a global option to the setup script (e.g. ``setup.py -q test``) or as an option for the ``test`` command itself (e.g. ``setup.py test -q``). There is one other option available: ``--test-suite=NAME, -s NAME`` Specify the test suite (or module, class, or method) to be run (e.g. ``some_module.test_suite``). The default for this option can be set by giving a ``test_suite`` argument to the ``setup()`` function, e.g.:: setup( # ... test_suite = "my_package.tests.test_all" ) If you did not set a ``test_suite`` in your ``setup()`` call, and do not provide a ``--test-suite`` option, an error will occur. ``upload`` - Upload source and/or egg distributions to PyPI =========================================================== PyPI now supports uploading project files for redistribution; uploaded files are easily found by EasyInstall, even if you don't have download links on your project's home page. Although Python 2.5 will support uploading all types of distributions to PyPI, setuptools only supports source distributions and eggs. (This is partly because PyPI's upload support is currently broken for various other file types.) To upload files, you must include the ``upload`` command *after* the ``sdist`` or ``bdist_egg`` commands on the setup command line. For example:: setup.py bdist_egg upload # create an egg and upload it setup.py sdist upload # create a source distro and upload it setup.py sdist bdist_egg upload # create and upload both Note that to upload files for a project, the corresponding version must already be registered with PyPI, using the distutils ``register`` command. It's usually a good idea to include the ``register`` command at the start of the command line, so that any registration problems can be found and fixed before building and uploading the distributions, e.g.:: setup.py register sdist bdist_egg upload This will update PyPI's listing for your project's current version. Note, by the way, that the metadata in your ``setup()`` call determines what will be listed in PyPI for your package. Try to fill out as much of it as possible, as it will save you a lot of trouble manually adding and updating your PyPI listings. Just put it in ``setup.py`` and use the ``register`` comamnd to keep PyPI up to date. The ``upload`` command has a few options worth noting: ``--sign, -s`` Sign each uploaded file using GPG (GNU Privacy Guard). The ``gpg`` program must be available for execution on the system ``PATH``. ``--show-response`` Display the full response text from server; this is useful for debugging PyPI problems. ``--repository=URL, -r URL`` The URL of the repository to upload to. Defaults to http://www.python.org/pypi (i.e., the main PyPI installation). ------------------------------------ Extending and Reusing ``setuptools`` ------------------------------------ Sorry, this section isn't written yet, and neither is a lot of what's below this point, except for the change log. You might want to `subscribe to changes in this page `_ to see when new documentation is added or updated. Adding Commands =============== You can create add-on packages that extend setuptools with additional commands by defining entry points in the ``distutils.commands`` group. For example, if you wanted to add a ``foo`` command, you might add something like this to your setup script:: setup( # ... entry_points = { "distutils.commands": [ "foo = mypackage.some_module:foo", ], }, ) Assuming, of course, that the ``foo`` class in ``mypackage.some_module`` is a ``setuptools.Command`` subclass. Once a project containing such entry points has been activated on ``sys.path``, (e.g. by running "install" or "develop" with a site-packages installation directory) the command(s) will be available to any ``setuptools``-based setup scripts. It is not necessary to use the ``--command-packages`` option or to monkeypatch the ``distutils.command`` package to install your commands; ``setuptools`` automatically adds a wrapper to the distutils to search for entry points in the active distributions on ``sys.path``. In fact, this is how setuptools' own commands are installed: the setuptools setup script defines entry points for them. Subclassing ``Command`` ----------------------- XXX Utility Modules =============== ``ez_setup`` ------------ XXX ``setuptools.archive_util`` --------------------------- XXX ``setuptools.sandbox`` ---------------------- XXX ``setuptools.package_index`` ---------------------------- XXX ---------------------------- Release Notes/Change History ---------------------------- 0.6a1 * Fixed the ``--tag-svn-revision`` option of ``egg_info`` not finding the latest revision number; it was using the revision number of the directory containing ``setup.py``, not the highest revision number in the project. * Added ``eager_resources`` setup argument * Fixed some problems using ``pkg_resources`` w/PEP 302 loaders other than ``zipimport``, and the previously-broken "eager resource" support. * Fixed ``pkg_resources.resource_exists()`` not working correctly, along with some other resource API bugs. * Added ``entry_points`` argument to ``setup()`` * Many ``pkg_resources`` API changes and enhancements: * Added ``EntryPoint``, ``get_entry_map``, ``load_entry_point``, and ``get_entry_info`` APIs for dynamic plugin discovery. * ``list_resources`` is now ``resource_listdir`` (and it actually works) * Resource API functions like ``resource_string()`` that accepted a package name and resource name, will now also accept a ``Requirement`` object in place of the package name (to allow access to non-package data files in an egg). * ``get_provider()`` will now accept a ``Requirement`` instance or a module name. If it is given a ``Requirement``, it will return a corresponding ``Distribution`` (by calling ``require()`` if a suitable distribution isn't already in the working set), rather than returning a metadata and resource provider for a specific module. (The difference is in how resource paths are interpreted; supplying a module name means resources path will be module-relative, rather than relative to the distribution's root.) * ``Distribution`` objects now implement the ``IResourceProvider`` and ``IMetadataProvider`` interfaces, so you don't need to reference the (no longer available) ``metadata`` attribute to get at these interfaces. * ``Distribution`` and ``Requirement`` both have a ``project_name`` attribute for the project name they refer to. (Previously these were ``name`` and ``distname`` attributes.) * The ``path`` attribute of ``Distribution`` objects is now ``location``, because it isn't necessarily a filesystem path (and hasn't been for some time now). The ``location`` of ``Distribution`` objects in the filesystem should always be normalized using ``pkg_resources.normalize_path()``; all of the setuptools and EasyInstall code that generates distributions from the filesystem (including ``Distribution.from_filename()``) ensure this invariant, but if you use a more generic API like ``Distribution()`` or ``Distribution.from_location()`` you should take care that you don't create a distribution with an un-normalized filesystem path. * ``Distribution`` objects now have an ``as_requirement()`` method that returns a ``Requirement`` for the distribution's project name and version. * Distribution objects no longer have an ``installed_on()`` method, and the ``install_on()`` method is now ``activate()`` (but may go away altogether soon). The ``depends()`` method has also been renamed to ``requires()``, and ``InvalidOption`` is now ``UnknownExtra``. * ``find_distributions()`` now takes an additional argument called ``only``, that tells it to only yield distributions whose location is the passed-in path. (It defaults to False, so that the default behavior is unchanged.) * The ``resolve()`` method of ``AvailableDistributions`` is now a method of ``WorkingSet`` instead, and the ``best_match()`` method now uses a working set instead of a path list as its second argument. * There is a new ``pkg_resources.add_activation_listener()`` API that lets you register a callback for notifications about distributions added to ``sys.path`` (including the distributions already on it). This is basically a hook for extensible applications and frameworks to be able to search for plugin metadata in distributions added at runtime. 0.5a13 * Fixed a bug in resource extraction from nested packages in a zipped egg. 0.5a12 * The zip-safety scanner now checks for modules that might be used with ``python -m``, and marks them as unsafe for zipping, since Python 2.4 can't handle ``-m`` on zipped modules. * Updated extraction/cache mechanism for zipped resources to avoid inter- process and inter-thread races during extraction. The default cache location can now be set via the ``PYTHON_EGGS_CACHE`` environment variable, and the default Windows cache is now a ``Python-Eggs`` subdirectory of the current user's "Application Data" directory, if the ``PYTHON_EGGS_CACHE`` variable isn't set. 0.5a11 * Fix breakage of the "develop" command that was caused by the addition of ``--always-unzip`` to the ``easy_install`` command. 0.5a10 * Fix a problem with ``pkg_resources`` being confused by non-existent eggs on ``sys.path`` (e.g. if a user deletes an egg without removing it from the ``easy-install.pth`` file). * Fix a problem with "basket" support in ``pkg_resources``, where egg-finding never actually went inside ``.egg`` files. * Made ``pkg_resources`` import the module you request resources from, if it's not already imported. 0.5a9 * Include ``svn:externals`` directories in source distributions as well as normal subversion-controlled files and directories. * Added ``exclude=patternlist`` option to ``setuptools.find_packages()`` * Changed --tag-svn-revision to include an "r" in front of the revision number for better readability. * Added ability to build eggs without including source files (except for any scripts, of course), using the ``--exclude-source-files`` option to ``bdist_egg``. * ``setup.py install`` now automatically detects when an "unmanaged" package or module is going to be on ``sys.path`` ahead of a package being installed, thereby preventing the newer version from being imported. If this occurs, a warning message is output to ``sys.stderr``, but installation proceeds anyway. The warning message informs the user what files or directories need deleting, and advises them they can also use EasyInstall (with the ``--delete-conflicting`` option) to do it automatically. * The ``egg_info`` command now adds a ``top_level.txt`` file to the metadata directory that lists all top-level modules and packages in the distribution. This is used by the ``easy_install`` command to find possibly-conflicting "unmanaged" packages when installing the distribution. * Added ``zip_safe`` and ``namespace_packages`` arguments to ``setup()``. Added package analysis to determine zip-safety if the ``zip_safe`` flag is not given, and advise the author regarding what code might need changing. * Fixed the swapped ``-d`` and ``-b`` options of ``bdist_egg``. 0.5a8 * The "egg_info" command now always sets the distribution metadata to "safe" forms of the distribution name and version, so that distribution files will be generated with parseable names (i.e., ones that don't include '-' in the name or version). Also, this means that if you use the various ``--tag`` options of "egg_info", any distributions generated will use the tags in the version, not just egg distributions. * Added support for defining command aliases in distutils configuration files, under the "[aliases]" section. To prevent recursion and to allow aliases to call the command of the same name, a given alias can be expanded only once per command-line invocation. You can define new aliases with the "alias" command, either for the local, global, or per-user configuration. * Added "rotate" command to delete old distribution files, given a set of patterns to match and the number of files to keep. (Keeps the most recently-modified distribution files matching each pattern.) * Added "saveopts" command that saves all command-line options for the current invocation to the local, global, or per-user configuration file. Useful for setting defaults without having to hand-edit a configuration file. * Added a "setopt" command that sets a single option in a specified distutils configuration file. 0.5a7 * Added "upload" support for egg and source distributions, including a bug fix for "upload" and a temporary workaround for lack of .egg support in PyPI. 0.5a6 * Beefed up the "sdist" command so that if you don't have a MANIFEST.in, it will include all files under revision control (CVS or Subversion) in the current directory, and it will regenerate the list every time you create a source distribution, not just when you tell it to. This should make the default "do what you mean" more often than the distutils' default behavior did, while still retaining the old behavior in the presence of MANIFEST.in. * Fixed the "develop" command always updating .pth files, even if you specified ``-n`` or ``--dry-run``. * Slightly changed the format of the generated version when you use ``--tag-build`` on the "egg_info" command, so that you can make tagged revisions compare *lower* than the version specified in setup.py (e.g. by using ``--tag-build=dev``). 0.5a5 * Added ``develop`` command to ``setuptools``-based packages. This command installs an ``.egg-link`` pointing to the package's source directory, and script wrappers that ``execfile()`` the source versions of the package's scripts. This lets you put your development checkout(s) on sys.path without having to actually install them. (To uninstall the link, use use ``setup.py develop --uninstall``.) * Added ``egg_info`` command to ``setuptools``-based packages. This command just creates or updates the "projectname.egg-info" directory, without building an egg. (It's used by the ``bdist_egg``, ``test``, and ``develop`` commands.) * Enhanced the ``test`` command so that it doesn't install the package, but instead builds any C extensions in-place, updates the ``.egg-info`` metadata, adds the source directory to ``sys.path``, and runs the tests directly on the source. This avoids an "unmanaged" installation of the package to ``site-packages`` or elsewhere. * Made ``easy_install`` a standard ``setuptools`` command, moving it from the ``easy_install`` module to ``setuptools.command.easy_install``. Note that if you were importing or extending it, you must now change your imports accordingly. ``easy_install.py`` is still installed as a script, but not as a module. 0.5a4 * Setup scripts using setuptools can now list their dependencies directly in the setup.py file, without having to manually create a ``depends.txt`` file. The ``install_requires`` and ``extras_require`` arguments to ``setup()`` are used to create a dependencies file automatically. If you are manually creating ``depends.txt`` right now, please switch to using these setup arguments as soon as practical, because ``depends.txt`` support will be removed in the 0.6 release cycle. For documentation on the new arguments, see the ``setuptools.dist.Distribution`` class. * Setup scripts using setuptools now always install using ``easy_install`` internally, for ease of uninstallation and upgrading. Note: you *must* remove any ``extra_path`` argument from your setup script, as it conflicts with the proper functioning of the ``easy_install`` command. * ``pkg_resources.AvailableDistributions.resolve()`` and related methods now accept an ``installer`` argument: a callable taking one argument, a ``Requirement`` instance. The callable must return a ``Distribution`` object, or ``None`` if no distribution is found. This feature is used by EasyInstall to resolve dependencies by recursively invoking itself. 0.5a1 * Added support for "self-installation" bootstrapping. Packages can now include ``ez_setup.py`` in their source distribution, and add the following to their ``setup.py``, in order to automatically bootstrap installation of setuptools as part of their setup process:: from ez_setup import use_setuptools use_setuptools() from setuptools import setup # etc... 0.4a4 * Fix problems with ``resource_listdir()``, ``resource_isdir()`` and resource directory extraction for zipped eggs. 0.4a3 * Fixed scripts not being able to see a ``__file__`` variable in ``__main__`` * Fixed a problem with ``resource_isdir()`` implementation that was introduced in 0.4a2. 0.4a2 * Added ``ez_setup.py`` installer/bootstrap script to make initial setuptools installation easier, and to allow distributions using setuptools to avoid having to include setuptools in their source distribution. * All downloads are now managed by the ``PackageIndex`` class (which is now subclassable and replaceable), so that embedders can more easily override download logic, give download progress reports, etc. The class has also been moved to the new ``setuptools.package_index`` module. * The ``Installer`` class no longer handles downloading, manages a temporary directory, or tracks the ``zip_ok`` option. Downloading is now handled by ``PackageIndex``, and ``Installer`` has become an ``easy_install`` command class based on ``setuptools.Command``. * There is a new ``setuptools.sandbox.run_setup()`` API to invoke a setup script in a directory sandbox, and a new ``setuptools.archive_util`` module with an ``unpack_archive()`` API. These were split out of EasyInstall to allow reuse by other tools and applications. * ``setuptools.Command`` now supports reinitializing commands using keyword arguments to set/reset options. Also, ``Command`` subclasses can now set their ``command_consumes_arguments`` attribute to ``True`` in order to receive an ``args`` option containing the rest of the command line. 0.4a1 * Fixed a bug in requirements processing for exact versions (i.e. ``==`` and ``!=``) when only one condition was included. * Added ``safe_name()`` and ``safe_version()`` APIs to clean up handling of arbitrary distribution names and versions found on PyPI. 0.3a4 * ``pkg_resources`` now supports resource directories, not just the resources in them. In particular, there are ``resource_listdir()`` and ``resource_isdir()`` APIs. * ``pkg_resources`` now supports "egg baskets" -- .egg zipfiles which contain multiple distributions in subdirectories whose names end with ``.egg``. Having such a "basket" in a directory on ``sys.path`` is equivalent to having the individual eggs in that directory, but the contained eggs can be individually added (or not) to ``sys.path``. Currently, however, there is no automated way to create baskets. * Namespace package manipulation is now protected by the Python import lock. 0.3a2 * Added new options to ``bdist_egg`` to allow tagging the egg's version number with a subversion revision number, the current date, or an explicit tag value. Run ``setup.py bdist_egg --help`` to get more information. * Misc. bug fixes 0.3a1 * Initial release.