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ReStructuredText
421 lines
15 KiB
ReStructuredText
PEP: 443
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Title: Single-dispatch generic functions
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Version: $Revision$
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Last-Modified: $Date$
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Author: Łukasz Langa <lukasz@python.org>
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Discussions-To: python-dev@python.org
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Status: Final
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Type: Standards Track
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Content-Type: text/x-rst
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Created: 22-May-2013
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Python-Version: 3.4
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Post-History: 22-May-2013, 25-May-2013, 31-May-2013
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Replaces: 245, 246, 3124
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Abstract
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========
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This PEP proposes a new mechanism in the ``functools`` standard library
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module that provides a simple form of generic programming known as
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single-dispatch generic functions.
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A **generic function** is composed of multiple functions implementing
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the same operation for different types. Which implementation should be
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used during a call is determined by the dispatch algorithm. When the
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implementation is chosen based on the type of a single argument, this is
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known as **single dispatch**.
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Rationale and Goals
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===================
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Python has always provided a variety of built-in and standard-library
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generic functions, such as ``len()``, ``iter()``, ``pprint.pprint()``,
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``copy.copy()``, and most of the functions in the ``operator`` module.
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However, it currently:
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1. does not have a simple or straightforward way for developers to
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create new generic functions,
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2. does not have a standard way for methods to be added to existing
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generic functions (i.e., some are added using registration
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functions, others require defining ``__special__`` methods, possibly
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by monkeypatching).
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In addition, it is currently a common anti-pattern for Python code to
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inspect the types of received arguments, in order to decide what to do
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with the objects.
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For example, code may wish to accept either an object
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of some type, or a sequence of objects of that type.
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Currently, the "obvious way" to do this is by type inspection, but this
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is brittle and closed to extension.
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Abstract Base Classes make it easier
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to discover present behaviour, but don't help adding new behaviour.
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A developer using an already-written library may be unable to change how
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their objects are treated by such code, especially if the objects they
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are using were created by a third party.
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Therefore, this PEP proposes a uniform API to address dynamic
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overloading using decorators.
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User API
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========
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To define a generic function, decorate it with the ``@singledispatch``
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decorator. Note that the dispatch happens on the type of the first
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argument. Create your function accordingly::
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>>> from functools import singledispatch
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>>> @singledispatch
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... def fun(arg, verbose=False):
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... if verbose:
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... print("Let me just say,", end=" ")
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... print(arg)
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To add overloaded implementations to the function, use the
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``register()`` attribute of the generic function. This is a decorator,
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taking a type parameter and decorating a function implementing the
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operation for that type::
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>>> @fun.register(int)
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... def _(arg, verbose=False):
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... if verbose:
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... print("Strength in numbers, eh?", end=" ")
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... print(arg)
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...
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>>> @fun.register(list)
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... def _(arg, verbose=False):
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... if verbose:
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... print("Enumerate this:")
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... for i, elem in enumerate(arg):
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... print(i, elem)
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To enable registering lambdas and pre-existing functions, the
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``register()`` attribute can be used in a functional form::
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>>> def nothing(arg, verbose=False):
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... print("Nothing.")
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...
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>>> fun.register(type(None), nothing)
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The ``register()`` attribute returns the undecorated function. This
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enables decorator stacking, pickling, as well as creating unit tests for
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each variant independently::
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>>> @fun.register(float)
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... @fun.register(Decimal)
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... def fun_num(arg, verbose=False):
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... if verbose:
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... print("Half of your number:", end=" ")
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... print(arg / 2)
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...
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>>> fun_num is fun
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False
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When called, the generic function dispatches on the type of the first
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argument::
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>>> fun("Hello, world.")
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Hello, world.
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>>> fun("test.", verbose=True)
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Let me just say, test.
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>>> fun(42, verbose=True)
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Strength in numbers, eh? 42
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>>> fun(['spam', 'spam', 'eggs', 'spam'], verbose=True)
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Enumerate this:
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0 spam
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1 spam
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2 eggs
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3 spam
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>>> fun(None)
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Nothing.
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>>> fun(1.23)
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0.615
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Where there is no registered implementation for a specific type, its
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method resolution order is used to find a more generic implementation.
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The original function decorated with ``@singledispatch`` is registered
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for the base ``object`` type, which means it is used if no better
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implementation is found.
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To check which implementation will the generic function choose for
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a given type, use the ``dispatch()`` attribute::
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>>> fun.dispatch(float)
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<function fun_num at 0x104319058>
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>>> fun.dispatch(dict) # note: default implementation
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<function fun at 0x103fe0000>
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To access all registered implementations, use the read-only ``registry``
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attribute::
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>>> fun.registry.keys()
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dict_keys([<class 'NoneType'>, <class 'int'>, <class 'object'>,
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<class 'decimal.Decimal'>, <class 'list'>,
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<class 'float'>])
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>>> fun.registry[float]
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<function fun_num at 0x1035a2840>
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>>> fun.registry[object]
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<function fun at 0x103fe0000>
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The proposed API is intentionally limited and opinionated, as to ensure
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it is easy to explain and use, as well as to maintain consistency with
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existing members in the ``functools`` module.
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Implementation Notes
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====================
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The functionality described in this PEP is already implemented in the
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``pkgutil`` standard library module as ``simplegeneric``. Because this
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implementation is mature, the goal is to move it largely as-is. The
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reference implementation is available on hg.python.org [#ref-impl]_.
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The dispatch type is specified as a decorator argument. An alternative
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form using function annotations was considered but its inclusion
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has been rejected. As of May 2013, this usage pattern is out of scope
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for the standard library [#pep-0008]_, and the best practices for
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annotation usage are still debated.
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Based on the current ``pkgutil.simplegeneric`` implementation, and
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following the convention on registering virtual subclasses on Abstract
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Base Classes, the dispatch registry will not be thread-safe.
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Abstract Base Classes
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---------------------
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The ``pkgutil.simplegeneric`` implementation relied on several forms of
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method resolution order (MRO). ``@singledispatch`` removes special
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handling of old-style classes and Zope's ExtensionClasses. More
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importantly, it introduces support for Abstract Base Classes (ABC).
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When a generic function implementation is registered for an ABC, the
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dispatch algorithm switches to an extended form of C3 linearization,
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which includes the relevant ABCs in the MRO of the provided argument.
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The algorithm inserts ABCs where their functionality is introduced, i.e.
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``issubclass(cls, abc)`` returns ``True`` for the class itself but
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returns ``False`` for all its direct base classes. Implicit ABCs for
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a given class (either registered or inferred from the presence of
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a special method like ``__len__()``) are inserted directly after the
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last ABC explicitly listed in the MRO of said class.
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In its most basic form, this linearization returns the MRO for the given
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type::
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>>> _compose_mro(dict, [])
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[<class 'dict'>, <class 'object'>]
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When the second argument contains ABCs that the specified type is
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a subclass of, they are inserted in a predictable order::
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>>> _compose_mro(dict, [Sized, MutableMapping, str,
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... Sequence, Iterable])
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[<class 'dict'>, <class 'collections.abc.MutableMapping'>,
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<class 'collections.abc.Mapping'>, <class 'collections.abc.Sized'>,
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<class 'collections.abc.Iterable'>, <class 'collections.abc.Container'>,
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<class 'object'>]
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While this mode of operation is significantly slower, all dispatch
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decisions are cached. The cache is invalidated on registering new
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implementations on the generic function or when user code calls
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``register()`` on an ABC to implicitly subclass it. In the latter case,
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it is possible to create a situation with ambiguous dispatch, for
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instance::
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>>> from collections.abc import Iterable, Container
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>>> class P:
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... pass
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>>> Iterable.register(P)
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<class '__main__.P'>
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>>> Container.register(P)
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<class '__main__.P'>
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Faced with ambiguity, ``@singledispatch`` refuses the temptation to
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guess::
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>>> @singledispatch
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... def g(arg):
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... return "base"
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...
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>>> g.register(Iterable, lambda arg: "iterable")
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<function <lambda> at 0x108b49110>
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>>> g.register(Container, lambda arg: "container")
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<function <lambda> at 0x108b491c8>
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>>> g(P())
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Traceback (most recent call last):
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...
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RuntimeError: Ambiguous dispatch: <class 'collections.abc.Container'>
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or <class 'collections.abc.Iterable'>
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Note that this exception would not be raised if one or more ABCs had
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been provided explicitly as base classes during class definition. In
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this case dispatch happens in the MRO order::
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>>> class Ten(Iterable, Container):
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... def __iter__(self):
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... for i in range(10):
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... yield i
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... def __contains__(self, value):
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... return value in range(10)
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...
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>>> g(Ten())
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'iterable'
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A similar conflict arises when subclassing an ABC is inferred from the
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presence of a special method like ``__len__()`` or ``__contains__()``::
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>>> class Q:
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... def __contains__(self, value):
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... return False
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...
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>>> issubclass(Q, Container)
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True
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>>> Iterable.register(Q)
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>>> g(Q())
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Traceback (most recent call last):
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...
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RuntimeError: Ambiguous dispatch: <class 'collections.abc.Container'>
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or <class 'collections.abc.Iterable'>
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An early version of the PEP contained a custom approach that was simpler
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but created a number of edge cases with surprising results [#why-c3]_.
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Usage Patterns
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==============
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This PEP proposes extending behaviour only of functions specifically
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marked as generic. Just as a base class method may be overridden by
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a subclass, so too a function may be overloaded to provide custom
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functionality for a given type.
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Universal overloading does not equal *arbitrary* overloading, in the
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sense that we need not expect people to randomly redefine the behavior
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of existing functions in unpredictable ways. To the contrary, generic
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function usage in actual programs tends to follow very predictable
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patterns and registered implementations are highly-discoverable in the
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common case.
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If a module is defining a new generic operation, it will usually also
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define any required implementations for existing types in the same
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place. Likewise, if a module is defining a new type, then it will
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usually define implementations there for any generic functions that it
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knows or cares about. As a result, the vast majority of registered
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implementations can be found adjacent to either the function being
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overloaded, or to a newly-defined type for which the implementation is
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adding support.
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It is only in rather infrequent cases that one will have implementations
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registered in a module that contains neither the function nor the
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type(s) for which the implementation is added. In the absence of
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incompetence or deliberate intention to be obscure, the few
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implementations that are not registered adjacent to the relevant type(s)
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or function(s), will generally not need to be understood or known about
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outside the scope where those implementations are defined. (Except in
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the "support modules" case, where best practice suggests naming them
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accordingly.)
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As mentioned earlier, single-dispatch generics are already prolific
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throughout the standard library. A clean, standard way of doing them
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provides a way forward to refactor those custom implementations to use
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a common one, opening them up for user extensibility at the same time.
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Alternative approaches
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======================
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In :pep:`3124` Phillip J. Eby proposes a full-grown solution
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with overloading based on arbitrary rule sets (with the default
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implementation dispatching on argument types), as well as interfaces,
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adaptation and method combining. PEAK-Rules [#peak-rules]_ is
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a reference implementation of the concepts described in PJE's PEP.
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Such a broad approach is inherently complex, which makes reaching
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a consensus hard. In contrast, this PEP focuses on a single piece of
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functionality that is simple to reason about. It's important to note
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this does not preclude the use of other approaches now or in the future.
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In a 2005 article on Artima [#artima2005]_ Guido van Rossum presents
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a generic function implementation that dispatches on types of all
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arguments on a function. The same approach was chosen in Andrey Popp's
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``generic`` package available on PyPI [#pypi-generic]_, as well as David
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Mertz's ``gnosis.magic.multimethods`` [#gnosis-multimethods]_.
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While this seems desirable at first, I agree with Fredrik Lundh's
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comment that "if you design APIs with pages of logic just to sort out
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what code a function should execute, you should probably hand over the
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API design to someone else". In other words, the single argument
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approach proposed in this PEP is not only easier to implement but also
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clearly communicates that dispatching on a more complex state is an
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anti-pattern. It also has the virtue of corresponding directly with the
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familiar method dispatch mechanism in object oriented programming. The
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only difference is whether the custom implementation is associated more
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closely with the data (object-oriented methods) or the algorithm
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(single-dispatch overloading).
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PyPy's RPython offers ``extendabletype`` [#pairtype]_, a metaclass which
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enables classes to be externally extended. In combination with
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``pairtype()`` and ``pair()`` factories, this offers a form of
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single-dispatch generics.
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Acknowledgements
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================
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Apart from Phillip J. Eby's work on :pep:`3124` and
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PEAK-Rules, influences include Paul Moore's original issue
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[#issue-5135]_ that proposed exposing ``pkgutil.simplegeneric`` as part
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of the ``functools`` API, Guido van Rossum's article on multimethods
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[#artima2005]_, and discussions with Raymond Hettinger on a general
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pprint rewrite. Huge thanks to Alyssa Coghlan for encouraging me to create
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this PEP and providing initial feedback.
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References
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==========
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.. [#ref-impl]
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http://hg.python.org/features/pep-443/file/tip/Lib/functools.py#l359
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.. [#pep-0008] :pep:`8` states in the "Programming Recommendations"
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section that "the Python standard library will not use function
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annotations as that would result in a premature commitment to
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a particular annotation style".
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.. [#why-c3] http://bugs.python.org/issue18244
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.. [#peak-rules] http://peak.telecommunity.com/DevCenter/PEAK_2dRules
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.. [#artima2005]
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http://www.artima.com/weblogs/viewpost.jsp?thread=101605
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.. [#pypi-generic] http://pypi.python.org/pypi/generic
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.. [#gnosis-multimethods]
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http://gnosis.cx/publish/programming/charming_python_b12.html
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.. [#pairtype]
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https://bitbucket.org/pypy/pypy/raw/default/rpython/tool/pairtype.py
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.. [#issue-5135] http://bugs.python.org/issue5135
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Copyright
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=========
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This document has been placed in the public domain.
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..
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Local Variables:
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mode: indented-text
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indent-tabs-mode: nil
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sentence-end-double-space: t
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fill-column: 70
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coding: utf-8
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End:
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