Creating Plugins¶
After a lot of trial and error, the easiest way I have found to define an API is to follow these steps:
Use the abc module to create a base abstract class to define the behaviors required of plugins of the API. Developers don’t have to subclass from the base class, but it provides a convenient way to document the API, and using an abstract base class keeps you honest.
Create plugins by subclassing the base class and implementing the required methods.
Define a unique namespace for each API by combining the name of the application (or library) and a name of the API. Keep it shallow. For example, “cliff.formatters” or “ceilometer.pollsters.compute”.
Example Plugin Set¶
The example program in this tutorial will create a plugin set with several data formatters, like what might be used by a command line program to prepare data to be printed to the console. Each formatter will take as input a dictionary with string keys and built-in data types as values. It will return as output an iterator that produces the string with the data structure formatted based on the rules of the specific formatter being used. The formatter’s constructor lets the caller specify the maximum width the output should have.
A Plugin Base Class¶
Step 1 above is to define an abstract base class for the API that needs to be implemented by each plugin.
# stevedore/example/base.py
import abc
import six
@six.add_metaclass(abc.ABCMeta)
class FormatterBase(object):
"""Base class for example plugin used in the tutorial.
"""
def __init__(self, max_width=60):
self.max_width = max_width
@abc.abstractmethod
def format(self, data):
"""Format the data and return unicode text.
:param data: A dictionary with string keys and simple types as
values.
:type data: dict(str:?)
:returns: Iterable producing the formatted text.
"""
The constructor is a concrete method because subclasses do not need to
override it, but the format()
method does not do anything useful
because there is no “default” implementation available.
Concrete Plugins¶
The next step is to create a couple of plugin classes with concrete
implementations of format()
. A simple example formatter produces
output with each variable name and value on a single line.
# stevedore/example/simple.py
from stevedore.example import base
class Simple(base.FormatterBase):
"""A very basic formatter.
"""
def format(self, data):
"""Format the data and return unicode text.
:param data: A dictionary with string keys and simple types as
values.
:type data: dict(str:?)
"""
for name, value in sorted(data.items()):
line = '{name} = {value}\n'.format(
name=name,
value=value,
)
yield line
There are plenty of other formatting options, but this example will give us enough to work with to demonstrate registering and using plugins.
Registering the Plugins¶
To use setuptools entry points, you must package your application or library using setuptools. The build and packaging process generates metadata which is available after installation to find the plugins provided by each python distribution.
The entry points must be declared as belonging to a specific namespace, so we need to pick one before going any further. These plugins are formatters from the stevedore examples, so I will use the namespace “stevedore.example.formatter”. Now it is possible to provide all of the necessary information in the packaging instructions:
# stevedore/example/setup.py
from setuptools import setup, find_packages
setup(
name='stevedore-examples',
version='1.0',
description='Demonstration package for stevedore',
author='Doug Hellmann',
author_email='doug@doughellmann.com',
url='http://opendev.org/openstack/stevedore',
classifiers=['Development Status :: 3 - Alpha',
'License :: OSI Approved :: Apache Software License',
'Programming Language :: Python',
'Programming Language :: Python :: 2',
'Programming Language :: Python :: 2.7',
'Programming Language :: Python :: 3',
'Programming Language :: Python :: 3.5',
'Intended Audience :: Developers',
'Environment :: Console',
],
platforms=['Any'],
scripts=[],
provides=['stevedore.examples',
],
packages=find_packages(),
include_package_data=True,
entry_points={
'stevedore.example.formatter': [
'simple = stevedore.example.simple:Simple',
'plain = stevedore.example.simple:Simple',
],
},
zip_safe=False,
)
The important lines are near the bottom where the entry_points
argument to setup()
is set. The value is a dictionary mapping
the namespace for the plugins to a list of their definitions. Each
item in the list should be a string with name = module:importable
where name is the user-visible name for the plugin, module is the
Python import reference for the module, and importable is the name
of something that can be imported from inside the module.
'simple = stevedore.example.simple:Simple',
'plain = stevedore.example.simple:Simple',
],
},
zip_safe=False,
)
In this case, there are two plugins registered. The “simple” plugin defined above, and a “plain” plugin, which is just an alias for the simple plugin.
setuptools Metadata¶
During the build, setuptools copies entry point definitions to a file
in the “.egg-info” directory for the package. For example, the file
for stevedore is located in stevedore.egg-info/entry_points.txt
:
[stevedore.example.formatter]
simple = stevedore.example.simple:Simple
plain = stevedore.example.simple:Simple
[stevedore.test.extension]
t2 = stevedore.tests.test_extension:FauxExtension
t1 = stevedore.tests.test_extension:FauxExtension
pkg_resources
uses the entry_points.txt
file from all of
the installed packages on the import path to find plugins. You should
not modify these files, except by changing the list of entry points in
setup.py
.
Adding Plugins in Other Packages¶
Part of the appeal of using entry points for plugins is that they can be distributed independently of an application. The namespace setuptools uses to find the plugins is different from the Python source code namespace. It is common to use a plugin namespace prefixed with the name of the application or library that loads the plugins, to ensure it is unique, but that name has no bearing on what Python package the code for the plugin should live in.
For example, we can add an alternate implementation of a formatter plugin that produces a reStructuredText field list.
# stevedore/example2/fields.py
import textwrap
from stevedore.example import base
class FieldList(base.FormatterBase):
"""Format values as a reStructuredText field list.
For example::
: name1 : value
: name2 : value
: name3 : a long value
will be wrapped with
a hanging indent
"""
def format(self, data):
"""Format the data and return unicode text.
:param data: A dictionary with string keys and simple types as
values.
:type data: dict(str:?)
"""
for name, value in sorted(data.items()):
full_text = ': {name} : {value}'.format(
name=name,
value=value,
)
wrapped_text = textwrap.fill(
full_text,
initial_indent='',
subsequent_indent=' ',
width=self.max_width,
)
yield wrapped_text + '\n'
The new plugin can then be packaged using a setup.py
containing
# stevedore/example2/setup.py
from setuptools import setup, find_packages
setup(
name='stevedore-examples2',
version='1.0',
description='Demonstration package for stevedore',
author='Doug Hellmann',
author_email='doug@doughellmann.com',
url='http://opendev.org/openstack/stevedore',
classifiers=['Development Status :: 3 - Alpha',
'License :: OSI Approved :: Apache Software License',
'Programming Language :: Python',
'Programming Language :: Python :: 2',
'Programming Language :: Python :: 2.7',
'Programming Language :: Python :: 3',
'Programming Language :: Python :: 3.5',
'Intended Audience :: Developers',
'Environment :: Console',
],
platforms=['Any'],
scripts=[],
provides=['stevedore.examples2',
],
packages=find_packages(),
include_package_data=True,
entry_points={
'stevedore.example.formatter': [
'field = stevedore.example2.fields:FieldList',
],
},
zip_safe=False,
)
The new plugin is in a separate stevedore-examples2
package.
setup(
name='stevedore-examples2',
However, the plugin is registered as part of the
stevedore.example.formatter
namespace.
'stevedore.example.formatter': [
'field = stevedore.example2.fields:FieldList',
],
},
When the plugin namespace is scanned, all packages on the current
PYTHONPATH
are examined and the entry point from the second
package is found and can be loaded without the application having to
know where the plugin is actually installed.