PEP: 435 Title: Adding an Enum type to the Python standard library Version: $Revision$ Last-Modified: $Date$ Author: Barry Warsaw , Eli Bendersky , Ethan Furman Status: Final Type: Standards Track Content-Type: text/x-rst Created: 23-Feb-2013 Python-Version: 3.4 Post-History: 2013-02-23, 2013-05-02 Replaces: 354 Resolution: https://mail.python.org/pipermail/python-dev/2013-May/126112.html Abstract ======== This PEP proposes adding an enumeration type to the Python standard library. An enumeration is a set of symbolic names bound to unique, constant values. Within an enumeration, the values can be compared by identity, and the enumeration itself can be iterated over. Status of discussions ===================== The idea of adding an enum type to Python is not new - PEP 354 [2]_ is a previous attempt that was rejected in 2005. Recently a new set of discussions was initiated [3]_ on the ``python-ideas`` mailing list. Many new ideas were proposed in several threads; after a lengthy discussion Guido proposed adding ``flufl.enum`` to the standard library [4]_. During the PyCon 2013 language summit the issue was discussed further. It became clear that many developers want to see an enum that subclasses ``int``, which can allow us to replace many integer constants in the standard library by enums with friendly string representations, without ceding backwards compatibility. An additional discussion among several interested core developers led to the proposal of having ``IntEnum`` as a special case of ``Enum``. The key dividing issue between ``Enum`` and ``IntEnum`` is whether comparing to integers is semantically meaningful. For most uses of enumerations, it's a **feature** to reject comparison to integers; enums that compare to integers lead, through transitivity, to comparisons between enums of unrelated types, which isn't desirable in most cases. For some uses, however, greater interoperability with integers is desired. For instance, this is the case for replacing existing standard library constants (such as ``socket.AF_INET``) with enumerations. Further discussion in late April 2013 led to the conclusion that enumeration members should belong to the type of their enum: ``type(Color.red) == Color``. Guido has pronounced a decision on this issue [5]_, as well as related issues of not allowing to subclass enums [6]_, unless they define no enumeration members [7]_. The PEP was accepted by Guido on May 10th, 2013 [1]_. Motivation ========== *[Based partly on the Motivation stated in PEP 354]* The properties of an enumeration are useful for defining an immutable, related set of constant values that may or may not have a semantic meaning. Classic examples are days of the week (Sunday through Saturday) and school assessment grades ('A' through 'D', and 'F'). Other examples include error status values and states within a defined process. It is possible to simply define a sequence of values of some other basic type, such as ``int`` or ``str``, to represent discrete arbitrary values. However, an enumeration ensures that such values are distinct from any others including, importantly, values within other enumerations, and that operations without meaning ("Wednesday times two") are not defined for these values. It also provides a convenient printable representation of enum values without requiring tedious repetition while defining them (i.e. no ``GREEN = 'green'``). Module and type name ==================== We propose to add a module named ``enum`` to the standard library. The main type exposed by this module is ``Enum``. Hence, to import the ``Enum`` type user code will run:: >>> from enum import Enum Proposed semantics for the new enumeration type =============================================== Creating an Enum ---------------- Enumerations are created using the class syntax, which makes them easy to read and write. An alternative creation method is described in `Functional API`_. To define an enumeration, subclass ``Enum`` as follows:: >>> from enum import Enum >>> class Color(Enum): ... red = 1 ... green = 2 ... blue = 3 **A note on nomenclature**: we call ``Color`` an *enumeration* (or *enum*) and ``Color.red``, ``Color.green`` are *enumeration members* (or *enum members*). Enumeration members also have *values* (the value of ``Color.red`` is ``1``, etc.) Enumeration members have human readable string representations:: >>> print(Color.red) Color.red ...while their ``repr`` has more information:: >>> print(repr(Color.red)) The *type* of an enumeration member is the enumeration it belongs to:: >>> type(Color.red) >>> isinstance(Color.green, Color) True >>> Enums also have a property that contains just their item name:: >>> print(Color.red.name) red Enumerations support iteration, in definition order:: >>> class Shake(Enum): ... vanilla = 7 ... chocolate = 4 ... cookies = 9 ... mint = 3 ... >>> for shake in Shake: ... print(shake) ... Shake.vanilla Shake.chocolate Shake.cookies Shake.mint Enumeration members are hashable, so they can be used in dictionaries and sets:: >>> apples = {} >>> apples[Color.red] = 'red delicious' >>> apples[Color.green] = 'granny smith' >>> apples {: 'red delicious', : 'granny smith'} Programmatic access to enumeration members ------------------------------------------ Sometimes it's useful to access members in enumerations programmatically (i.e. situations where ``Color.red`` won't do because the exact color is not known at program-writing time). ``Enum`` allows such access:: >>> Color(1) >>> Color(3) If you want to access enum members by *name*, use item access:: >>> Color['red'] >>> Color['green'] Duplicating enum members and values ----------------------------------- Having two enum members with the same name is invalid:: >>> class Shape(Enum): ... square = 2 ... square = 3 ... Traceback (most recent call last): ... TypeError: Attempted to reuse key: square However, two enum members are allowed to have the same value. Given two members A and B with the same value (and A defined first), B is an alias to A. By-value lookup of the value of A and B will return A. By-name lookup of B will also return A:: >>> class Shape(Enum): ... square = 2 ... diamond = 1 ... circle = 3 ... alias_for_square = 2 ... >>> Shape.square >>> Shape.alias_for_square >>> Shape(2) Iterating over the members of an enum does not provide the aliases:: >>> list(Shape) [, , ] The special attribute ``__members__`` is an ordered dictionary mapping names to members. It includes all names defined in the enumeration, including the aliases:: >>> for name, member in Shape.__members__.items(): ... name, member ... ('square', ) ('diamond', ) ('circle', ) ('alias_for_square', ) The ``__members__`` attribute can be used for detailed programmatic access to the enumeration members. For example, finding all the aliases:: >>> [name for name, member in Shape.__members__.items() if member.name != name] ['alias_for_square'] Comparisons ----------- Enumeration members are compared by identity:: >>> Color.red is Color.red True >>> Color.red is Color.blue False >>> Color.red is not Color.blue True Ordered comparisons between enumeration values are *not* supported. Enums are not integers (but see `IntEnum`_ below):: >>> Color.red < Color.blue Traceback (most recent call last): File "", line 1, in TypeError: unorderable types: Color() < Color() Equality comparisons are defined though:: >>> Color.blue == Color.red False >>> Color.blue != Color.red True >>> Color.blue == Color.blue True Comparisons against non-enumeration values will always compare not equal (again, ``IntEnum`` was explicitly designed to behave differently, see below):: >>> Color.blue == 2 False Allowed members and attributes of enumerations ---------------------------------------------- The examples above use integers for enumeration values. Using integers is short and handy (and provided by default by the `Functional API`_), but not strictly enforced. In the vast majority of use-cases, one doesn't care what the actual value of an enumeration is. But if the value *is* important, enumerations can have arbitrary values. Enumerations are Python classes, and can have methods and special methods as usual. If we have this enumeration:: class Mood(Enum): funky = 1 happy = 3 def describe(self): # self is the member here return self.name, self.value def __str__(self): return 'my custom str! {0}'.format(self.value) @classmethod def favorite_mood(cls): # cls here is the enumeration return cls.happy Then:: >>> Mood.favorite_mood() >>> Mood.happy.describe() ('happy', 3) >>> str(Mood.funky) 'my custom str! 1' The rules for what is allowed are as follows: all attributes defined within an enumeration will become members of this enumeration, with the exception of *__dunder__* names and descriptors [9]_; methods are descriptors too. Restricted subclassing of enumerations -------------------------------------- Subclassing an enumeration is allowed only if the enumeration does not define any members. So this is forbidden:: >>> class MoreColor(Color): ... pink = 17 ... TypeError: Cannot extend enumerations But this is allowed:: >>> class Foo(Enum): ... def some_behavior(self): ... pass ... >>> class Bar(Foo): ... happy = 1 ... sad = 2 ... The rationale for this decision was given by Guido in [6]_. Allowing to subclass enums that define members would lead to a violation of some important invariants of types and instances. On the other hand, it makes sense to allow sharing some common behavior between a group of enumerations, and subclassing empty enumerations is also used to implement ``IntEnum``. IntEnum ------- A variation of ``Enum`` is proposed which is also a subclass of ``int``. Members of an ``IntEnum`` can be compared to integers; by extension, integer enumerations of different types can also be compared to each other:: >>> from enum import IntEnum >>> class Shape(IntEnum): ... circle = 1 ... square = 2 ... >>> class Request(IntEnum): ... post = 1 ... get = 2 ... >>> Shape == 1 False >>> Shape.circle == 1 True >>> Shape.circle == Request.post True However they still can't be compared to ``Enum``:: >>> class Shape(IntEnum): ... circle = 1 ... square = 2 ... >>> class Color(Enum): ... red = 1 ... green = 2 ... >>> Shape.circle == Color.red False ``IntEnum`` values behave like integers in other ways you'd expect:: >>> int(Shape.circle) 1 >>> ['a', 'b', 'c'][Shape.circle] 'b' >>> [i for i in range(Shape.square)] [0, 1] For the vast majority of code, ``Enum`` is strongly recommended, since ``IntEnum`` breaks some semantic promises of an enumeration (by being comparable to integers, and thus by transitivity to other unrelated enumerations). It should be used only in special cases where there's no other choice; for example, when integer constants are replaced with enumerations and backwards compatibility is required with code that still expects integers. Other derived enumerations -------------------------- ``IntEnum`` will be part of the ``enum`` module. However, it would be very simple to implement independently:: class IntEnum(int, Enum): pass This demonstrates how similar derived enumerations can be defined, for example a ``StrEnum`` that mixes in ``str`` instead of ``int``. Some rules: 1. When subclassing Enum, mix-in types must appear before Enum itself in the sequence of bases, as in the ``IntEnum`` example above. 2. While Enum can have members of any type, once you mix in an additional type, all the members must have values of that type, e.g. ``int`` above. This restriction does not apply to mix-ins which only add methods and don't specify another data type such as ``int`` or ``str``. Pickling -------- Enumerations can be pickled and unpickled:: >>> from enum.tests.fruit import Fruit >>> from pickle import dumps, loads >>> Fruit.tomato is loads(dumps(Fruit.tomato)) True The usual restrictions for pickling apply: picklable enums must be defined in the top level of a module, since unpickling requires them to be importable from that module. Functional API -------------- The ``Enum`` class is callable, providing the following functional API:: >>> Animal = Enum('Animal', 'ant bee cat dog') >>> Animal >>> Animal.ant >>> Animal.ant.value 1 >>> list(Animal) [, , , ] The semantics of this API resemble ``namedtuple``. The first argument of the call to ``Enum`` is the name of the enumeration. Pickling enums created with the functional API will work on CPython and PyPy, but for IronPython and Jython you may need to specify the module name explicitly as follows:: >>> Animals = Enum('Animals', 'ant bee cat dog', module=__name__) The second argument is the *source* of enumeration member names. It can be a whitespace-separated string of names, a sequence of names, a sequence of 2-tuples with key/value pairs, or a mapping (e.g. dictionary) of names to values. The last two options enable assigning arbitrary values to enumerations; the others auto-assign increasing integers starting with 1. A new class derived from ``Enum`` is returned. In other words, the above assignment to ``Animal`` is equivalent to:: >>> class Animals(Enum): ... ant = 1 ... bee = 2 ... cat = 3 ... dog = 4 The reason for defaulting to ``1`` as the starting number and not ``0`` is that ``0`` is ``False`` in a boolean sense, but enum members all evaluate to ``True``. Proposed variations =================== Some variations were proposed during the discussions in the mailing list. Here's some of the more popular ones. flufl.enum ---------- ``flufl.enum`` was the reference implementation upon which this PEP was originally based. Eventually, it was decided against the inclusion of ``flufl.enum`` because its design separated enumeration members from enumerations, so the former are not instances of the latter. Its design also explicitly permits subclassing enumerations for extending them with more members (due to the member/enum separation, the type invariants are not violated in ``flufl.enum`` with such a scheme). Not having to specify values for enums -------------------------------------- Michael Foord proposed (and Tim Delaney provided a proof-of-concept implementation) to use metaclass magic that makes this possible:: class Color(Enum): red, green, blue The values get actually assigned only when first looked up. Pros: cleaner syntax that requires less typing for a very common task (just listing enumeration names without caring about the values). Cons: involves much magic in the implementation, which makes even the definition of such enums baffling when first seen. Besides, explicit is better than implicit. Using special names or forms to auto-assign enum values ------------------------------------------------------- A different approach to avoid specifying enum values is to use a special name or form to auto assign them. For example:: class Color(Enum): red = None # auto-assigned to 0 green = None # auto-assigned to 1 blue = None # auto-assigned to 2 More flexibly:: class Color(Enum): red = 7 green = None # auto-assigned to 8 blue = 19 purple = None # auto-assigned to 20 Some variations on this theme: #. A special name ``auto`` imported from the enum package. #. Georg Brandl proposed ellipsis (``...``) instead of ``None`` to achieve the same effect. Pros: no need to manually enter values. Makes it easier to change the enum and extend it, especially for large enumerations. Cons: actually longer to type in many simple cases. The argument of explicit vs. implicit applies here as well. Use-cases in the standard library ================================= The Python standard library has many places where the usage of enums would be beneficial to replace other idioms currently used to represent them. Such usages can be divided to two categories: user-code facing constants, and internal constants. User-code facing constants like ``os.SEEK_*``, ``socket`` module constants, decimal rounding modes and HTML error codes could require backwards compatibility since user code may expect integers. ``IntEnum`` as described above provides the required semantics; being a subclass of ``int``, it does not affect user code that expects integers, while on the other hand allowing printable representations for enumeration values:: >>> import socket >>> family = socket.AF_INET >>> family == 2 True >>> print(family) SocketFamily.AF_INET Internal constants are not seen by user code but are employed internally by stdlib modules. These can be implemented with ``Enum``. Some examples uncovered by a very partial skim through the stdlib: ``binhex``, ``imaplib``, ``http/client``, ``urllib/robotparser``, ``idlelib``, ``concurrent.futures``, ``turtledemo``. In addition, looking at the code of the Twisted library, there are many use cases for replacing internal state constants with enums. The same can be said about a lot of networking code (especially implementation of protocols) and can be seen in test protocols written with the Tulip library as well. Acknowledgments =============== This PEP was initially proposing including the ``flufl.enum`` package [8]_ by Barry Warsaw into the stdlib, and is inspired in large parts by it. Ben Finney is the author of the earlier enumeration PEP 354. References ========== .. [1] https://mail.python.org/pipermail/python-dev/2013-May/126112.html .. [2] http://www.python.org/dev/peps/pep-0354/ .. [3] https://mail.python.org/pipermail/python-ideas/2013-January/019003.html .. [4] https://mail.python.org/pipermail/python-ideas/2013-February/019373.html .. [5] To make enums behave similarly to Python classes like bool, and behave in a more intuitive way. It would be surprising if the type of ``Color.red`` would not be ``Color``. (Discussion in https://mail.python.org/pipermail/python-dev/2013-April/125687.html) .. [6] Subclassing enums and adding new members creates an unresolvable situation; on one hand ``MoreColor.red`` and ``Color.red`` should not be the same object, and on the other ``isinstance`` checks become confusing if they are not. The discussion also links to Stack Overflow discussions that make additional arguments. (https://mail.python.org/pipermail/python-dev/2013-April/125716.html) .. [7] It may be useful to have a class defining some behavior (methods, with no actual enumeration members) mixed into an enum, and this would not create the problem discussed in [6]_. (Discussion in https://mail.python.org/pipermail/python-dev/2013-May/125859.html) .. [8] http://pythonhosted.org/flufl.enum/ .. [9] http://docs.python.org/3/howto/descriptor.html Copyright ========= This document has been placed in the public domain. .. Local Variables: mode: indented-text indent-tabs-mode: nil sentence-end-double-space: t fill-column: 70 coding: utf-8 End: