I'm mainly a C# developer, but I'm currently working on a project in Python.

How can I represent the equivalent of an Enum in Python?


43 Answers 43


Enums have been added to Python 3.4 as described in PEP 435. It has also been backported to 3.3, 3.2, 3.1, 2.7, 2.6, 2.5, and 2.4 on pypi.

For more advanced Enum techniques try the aenum library (2.7, 3.3+, same author as enum34. Code is not perfectly compatible between py2 and py3, e.g. you'll need __order__ in python 2).

  • To use enum34, do $ pip install enum34
  • To use aenum, do $ pip install aenum

Installing enum (no numbers) will install a completely different and incompatible version.

from enum import Enum     # for enum34, or the stdlib version
# from aenum import Enum  # for the aenum version
Animal = Enum('Animal', 'ant bee cat dog')

Animal.ant  # returns <Animal.ant: 1>
Animal['ant']  # returns <Animal.ant: 1> (string lookup)
Animal.ant.name  # returns 'ant' (inverse lookup)

or equivalently:

class Animal(Enum):
    ant = 1
    bee = 2
    cat = 3
    dog = 4

In earlier versions, one way of accomplishing enums is:

def enum(**enums):
    return type('Enum', (), enums)

which is used like so:

>>> Numbers = enum(ONE=1, TWO=2, THREE='three')
>>> Numbers.ONE
>>> Numbers.TWO
>>> Numbers.THREE

You can also easily support automatic enumeration with something like this:

def enum(*sequential, **named):
    enums = dict(zip(sequential, range(len(sequential))), **named)
    return type('Enum', (), enums)

and used like so:

>>> Numbers = enum('ZERO', 'ONE', 'TWO')
>>> Numbers.ZERO
>>> Numbers.ONE

Support for converting the values back to names can be added this way:

def enum(*sequential, **named):
    enums = dict(zip(sequential, range(len(sequential))), **named)
    reverse = dict((value, key) for key, value in enums.iteritems())
    enums['reverse_mapping'] = reverse
    return type('Enum', (), enums)

This overwrites anything with that name, but it is useful for rendering your enums in output. It will throw a KeyError if the reverse mapping doesn't exist. With the first example:

>>> Numbers.reverse_mapping['three']

If you are using MyPy another way to express "enums" is with typing.Literal.

For example:

from typing import Literal #python >=3.8
from typing_extensions import Literal #python 2.7, 3.4-3.7

Animal = Literal['ant', 'bee', 'cat', 'dog']

def hello_animal(animal: Animal):
    print(f"hello {animal}")

hello_animal('rock') # error
hello_animal('bee') # passes

  • 2
    I was not been able to understand, why did they pass kwargs(**named) in the method enum(*sequential, **named) ? Please explains. Without kwargs also it will works. I checked it.
    – Seenu S
    Mar 10, 2017 at 5:52
  • 1
    It would be nice to update the Python 2 function to be compatible with Python 3's functional API of Enum(name, values)
    – bscan
    Mar 10, 2017 at 15:52
  • The var kwargs (**named) in the enum function for older versions is to support custom values: enum("blue", "red", "green", black=0)
    – merwok
    Jan 27, 2020 at 22:20
  • 1
    What about default values?
    – Sam
    Jul 4, 2021 at 3:02
  • 3
    One should mention auto() here. Apr 12, 2022 at 7:49

Before PEP 435, Python didn't have an equivalent but you could implement your own.

Myself, I like keeping it simple (I've seen some horribly complex examples on the net), something like this ...

class Animal:
    DOG = 1
    CAT = 2

x = Animal.DOG

In Python 3.4 (PEP 435), you can make Enum the base class. This gets you a little bit of extra functionality, described in the PEP. For example, enum members are distinct from integers, and they are composed of a name and a value.

from enum import Enum

class Animal(Enum):
    DOG = 1
    CAT = 2

# <Animal.DOG: 1>

# 1

# "DOG"

If you don't want to type the values, use the following shortcut:

class Animal(Enum):
    DOG, CAT = range(2)

Enum implementations can be converted to lists and are iterable. The order of its members is the declaration order and has nothing to do with their values. For example:

class Animal(Enum):
    DOG = 1
    CAT = 2
    COW = 0

# [<Animal.DOG: 1>, <Animal.CAT: 2>, <Animal.COW: 0>]

[animal.value for animal in Animal]
# [1, 2, 0]

Animal.CAT in Animal
# True
  • 256
    Python is dynamic by default. There's no valid reason to enforce compile-time safety in a language like Python, especially when there is none. And another thing ... a good pattern is only good in the context in which it was created. A good pattern can also be superseded or completely useless, depending on the tools you're using. Jul 21, 2009 at 8:21
  • 22
    @Longpoke if you have 100 values, then you're definitely doing something wrong ;) I like numbers associated with my enums ... they are easy to write (vs strings), can be easily persisted in a database, and are compatible with the C/C++ enum, which makes for easier marshaling. May 7, 2010 at 12:04
  • 51
    I use this, with the numbers replaced by object().
    – Tobu
    Jul 20, 2010 at 7:53
  • 8
    X = object() is inconvenient because it doesn't know what it is (you can only compare to namespace.X), and risky because copy.deepcopy() or serialization/deserialiaztion creates a new one, which isn't equal to any of those you defined! Numbers are at least safe, but strings are usually better. Jun 20, 2012 at 11:19
  • 9
    The original PEP354 is no longer merely rejected, but is now marked superseded. PEP435 adds a standard Enum for Python 3.4. See python.org/dev/peps/pep-0435 May 10, 2013 at 19:05

Here is one implementation:

class Enum(set):
    def __getattr__(self, name):
        if name in self:
            return name
        raise AttributeError

Here is its usage:

Animals = Enum(["DOG", "CAT", "HORSE"])

  • 56
    Excellent. This can be further improved by overriding __setattr__(self, name, value) and maybe __delattr__(self, name) so that if you accidentally write Animals.DOG = CAT, it won't silently succeed. Jan 11, 2011 at 14:12
  • 17
    @shahjapan: Interesting, but relatively slow: a test is done for each access like Animals.DOG; also, the values of the constats are strings, so that comparisons with these constants are slower than if, say, integers were allowed as values. Oct 25, 2011 at 12:48
  • 3
    @shahjapan: I would argue that this solution is not as legible as the shorter solutions of Alexandru or Mark, for instance. It's an interesting solution, though. :) Oct 31, 2011 at 9:39
  • I tried using setattr() function inside __init__() method instead of overidding __getattr__() method. I am assume this is supposed work the same way: class Enum(object): def __init__(self, enum_string_list): if type(enum_string_list) == list: for enum_string in enum_string_list: setattr(self, enum_string, enum_string) else: raise AttributeError Nov 15, 2012 at 5:43
  • 8
    @AndréTerra: how do you check for set membership in a try-except block?
    – bgusach
    Jan 30, 2015 at 11:57

If you need the numeric values, here's the quickest way:

dog, cat, rabbit = range(3)

In Python 3.x you can also add a starred placeholder at the end, which will soak up all the remaining values of the range in case you don't mind wasting memory and cannot count:

dog, cat, rabbit, horse, *_ = range(100)
  • 3
    But this might take more memory!
    – M.J
    Feb 28, 2019 at 4:42
  • I do not see the point of the starred placeholder given that Python will check the number of values to unpack (so it will do the counting for you). Sep 16, 2019 at 13:48
  • 1
    @GabrielDevillers, I think Python will raise an exception if there is a mismatch on number of elements in the tuple to assign. Sep 16, 2019 at 21:18
  • 1
    Indeed, it does in my test (Python2,3) but that means that any counting mistake from the programmer will be catched on first test (with a message giving the correct count). Sep 16, 2019 at 22:29

The best solution for you would depend on what you require from your fake enum.

Simple enum:

If you need the enum as only a list of names identifying different items, the solution by Mark Harrison (above) is great:

Pen, Pencil, Eraser = range(0, 3)

Using a range also allows you to set any starting value:

Pen, Pencil, Eraser = range(9, 12)

In addition to the above, if you also require that the items belong to a container of some sort, then embed them in a class:

class Stationery:
    Pen, Pencil, Eraser = range(0, 3)

To use the enum item, you would now need to use the container name and the item name:

stype = Stationery.Pen

Complex enum:

For long lists of enum or more complicated uses of enum, these solutions will not suffice. You could look to the recipe by Will Ware for Simulating Enumerations in Python published in the Python Cookbook. An online version of that is available here.

More info:

PEP 354: Enumerations in Python has the interesting details of a proposal for enum in Python and why it was rejected.

  • 9
    with range you can omit the first argument if it's 0 Jun 13, 2014 at 16:09
  • Another fake enum that suits some purposes is my_enum = dict(map(reversed, enumerate(str.split('Item0 Item1 Item2')))). Then my_enum can be used in look-up, e.g., my_enum['Item0'] can be an index into a sequence. You might want to wrap the result of str.split in a function that throws an exception if there are any duplicates.
    – Ana Nimbus
    Jun 2, 2018 at 3:51
  • Nice! For Flags you can Flag1, Flag2, Flag3 = [2**i for i in range(3)]
    – majkelx
    Sep 30, 2019 at 12:00

The typesafe enum pattern which was used in Java pre-JDK 5 has a number of advantages. Much like in Alexandru's answer, you create a class and class level fields are the enum values; however, the enum values are instances of the class rather than small integers. This has the advantage that your enum values don't inadvertently compare equal to small integers, you can control how they're printed, add arbitrary methods if that's useful and make assertions using isinstance:

class Animal:
   def __init__(self, name):
       self.name = name

   def __str__(self):
       return self.name

   def __repr__(self):
       return "<Animal: %s>" % self

Animal.DOG = Animal("dog")
Animal.CAT = Animal("cat")

>>> x = Animal.DOG
>>> x
<Animal: dog>
>>> x == 1

A recent thread on python-dev pointed out there are a couple of enum libraries in the wild, including:

  • 17
    I think this is a very bad approach. Animal.DOG = Animal("dog") Animal.DOG2 = Animal("dog") assert Animal.DOG == Animal.DOG2 fails...
    – Confusion
    Dec 19, 2009 at 11:05
  • 12
    @Confusion The user isn't supposed to call the constructor, the fact that there's even a constructor is an implementation detail and you have to communicate to who ever is using your code that making new enumeration values makes no sense and that exiting code will not "do the right thing". Of course that doesn't stop you from implementing Animal.from_name("dog") --> Animal.DOG. Dec 21, 2009 at 14:41
  • 14
    "the advantage that your enum values don't inadvertently compare equal to small integers" What's the advantage in this? What's wrong with comparing your enum to integers? Especially if you store the enum in the database, you usually want it to be stored as integers, so you'll have to compare it to integers at some point.
    – ibz
    Sep 21, 2010 at 20:23
  • 3
    @Aaaron Maenpaa. correct. It's still a broken and overly complicated way to do it. Sep 24, 2010 at 19:00
  • 4
    @AaronMcSmooth That really depends on whether you're coming in from the C perspective of "Enums are just names for a couple of ints" or the more object oriented approach where enum values are actual objects and have methods (which is how enums in Java 1.5 are, and which the type safe enum pattern was going for). Personally, I don't like switch statements so I lean towards enum values that are actual objects. Sep 24, 2010 at 19:31

An Enum class can be a one-liner.

class Enum(tuple): __getattr__ = tuple.index

How to use it (forward and reverse lookup, keys, values, items, etc.)

>>> State = Enum(['Unclaimed', 'Claimed'])
>>> State.Claimed
>>> State[1]
>>> State
('Unclaimed', 'Claimed')
>>> range(len(State))
[0, 1]
>>> [(k, State[k]) for k in range(len(State))]
[(0, 'Unclaimed'), (1, 'Claimed')]
>>> [(k, getattr(State, k)) for k in State]
[('Unclaimed', 0), ('Claimed', 1)]
  • 1
    I think it is the simplest end most elegant solution. In python 2.4 ( yes, old legacy server ) tuples haven't index. I solved replacing with list.
    – Massimo
    Jul 11, 2017 at 12:37
  • 1
    I tried this in a Jupyter notebook and discovered that it wouldn't work as a one-line definition, but that putting the getattr definition on a second (indented) line would be accepted. Jul 20, 2017 at 18:04
  • This solution let's me use the in keyword to search for members which is neat. Example usage: 'Claimed' in Enum(['Unclaimed', 'Claimed']) Jul 8, 2019 at 23:34
  • I don't like such string-initialization, because such type will not be handled by IntelliSense. So builtin type and custom of it is better
    – iperov
    Jun 22, 2021 at 14:20
  • Does this have an advantage over enum.Enum? Or is this just an answer that should be deleted, now that Python 3.6 is already deprecated and Python 3.4 introduced the built-in enum package? Jan 21, 2022 at 9:06

So, I agree. Let's not enforce type safety in Python, but I would like to protect myself from silly mistakes. So what do we think about this?

class Animal(object):
    values = ['Horse','Dog','Cat']

    class __metaclass__(type):
        def __getattr__(self, name):
            return self.values.index(name)

It keeps me from value-collision in defining my enums.

>>> Animal.Cat

There's another handy advantage: really fast reverse lookups:

def name_of(self, i):
    return self.values[i]
  • I like this, but you might as well lock values in for efficiency with a tuple? I played around with it and came up with a version that sets self.values from args in init. It is nice to be able to declare Animal = Enum('horse', 'dog', 'cat'). I also catch the ValueError in getattr in the event of a missing item in self.values -- it seems better to raise an AttributeError with the supplied name string instead. I couldn't get the metaclass to work in Python 2.7 based on my limited knowledge in that area, but my custom Enum class works fine with straight instance methods.
    – trojjer
    Nov 28, 2013 at 16:23
  • I do not have the faintest idea about how you use this class !?? Could you explain what you do with it ?
    – Camion
    Jul 16, 2021 at 1:33
  • Does this have an advantage over enum.Enum? Or is this just an answer that should be deleted, not that Python 3.6 is already deprecated and Python 3.4 introduced the built-in enum package? Jan 21, 2022 at 8:12

Python doesn't have a built-in equivalent to enum, and other answers have ideas for implementing your own (you may also be interested in the over the top version in the Python cookbook).

However, in situations where an enum would be called for in C, I usually end up just using simple strings: because of the way objects/attributes are implemented, (C)Python is optimized to work very fast with short strings anyway, so there wouldn't really be any performance benefit to using integers. To guard against typos / invalid values you can insert checks in selected places.

ANIMALS = ['cat', 'dog', 'python']

def take_for_a_walk(animal):
    assert animal in ANIMALS

(One disadvantage compared to using a class is that you lose the benefit of autocomplete)

  • 2
    I prefer this solution. I like to use built-in types where possible.
    – Seun Osewa
    Feb 3, 2009 at 18:01
  • That version isn't really over the top. It just has a lot of supplied testing code
    – Casebash
    Oct 25, 2009 at 5:10
  • 1
    Actually, the "correct" version is in the comments and is much more complex - the main version has a minor bug.
    – Casebash
    Oct 25, 2009 at 5:24

On 2013-05-10, Guido agreed to accept PEP 435 into the Python 3.4 standard library. This means that Python finally has builtin support for enumerations!

There is a backport available for Python 3.3, 3.2, 3.1, 2.7, 2.6, 2.5, and 2.4. It's on Pypi as enum34.


>>> from enum import Enum
>>> class Color(Enum):
...     red = 1
...     green = 2
...     blue = 3


>>> print(Color.red)
>>> print(repr(Color.red))
<Color.red: 1>


>>> for color in Color:
...   print(color)

Programmatic access:

>>> Color(1)
>>> Color['blue']

For more information, refer to the proposal. Official documentation will probably follow soon.


I prefer to define enums in Python like so:

class Animal:
  class Dog: pass
  class Cat: pass

x = Animal.Dog

It's more bug-proof than using integers since you don't have to worry about ensuring that the integers are unique (e.g. if you said Dog = 1 and Cat = 1 you'd be screwed).

It's more bug-proof than using strings since you don't have to worry about typos (e.g. x == "catt" fails silently, but x == Animal.Catt is a runtime exception).

ADDENDUM : You can even enhance this solution by having Dog and Cat inherit from a symbol class with the right metaclass :

class SymbolClass(type):
    def __repr__(self): return self.__qualname__
    def __str__(self): return self.__name__

class Symbol(metaclass=SymbolClass): pass

class Animal:
    class Dog(Symbol): pass
    class Cat(Symbol): pass

Then, if you use those values to e.g. index a dictionary, Requesting it's representation will make them appear nicely:

>>> mydict = {Animal.Dog: 'Wan Wan', Animal.Cat: 'Nyaa'}
>>> mydict
{Animal.Dog: 'Wan Wan', Animal.Cat: 'Nyaa'}
def M_add_class_attribs(attribs):
    def foo(name, bases, dict_):
        for v, k in attribs:
            dict_[k] = v
        return type(name, bases, dict_)
    return foo

def enum(*names):
    class Foo(object):
        __metaclass__ = M_add_class_attribs(enumerate(names))
        def __setattr__(self, name, value):  # this makes it read-only
            raise NotImplementedError
    return Foo()

Use it like this:

Animal = enum('DOG', 'CAT')
Animal.DOG # returns 0
Animal.CAT # returns 1
Animal.DOG = 2 # raises NotImplementedError

if you just want unique symbols and don't care about the values, replace this line:

__metaclass__ = M_add_class_attribs(enumerate(names))

with this:

__metaclass__ = M_add_class_attribs((object(), name) for name in names)
  • 11
    IMHO it would be cleaner if you changed enum(names) to enum(*names) - then you could drop the extra parenthesis when calling it.
    – Chris Lutz
    Nov 18, 2009 at 2:56
  • I like this approach. I actually changed it to set the attribute value to the same string as the name, which has the nice property that Animal.DOG == 'DOG', so they stringify themselves for you automatically. (Helps immensely for printing out debug output.) May 28, 2010 at 12:01
  • Does this have an advantage over enum.Enum? Or is this just an answer that should be deleted, now that Python 3.6 is already deprecated and Python 3.4 introduced the built-in enum package? Jan 21, 2022 at 9:05

Keep it simple, using old Python 2.x (see below for Python 3!):

class Enum(object): 
    def __init__(self, tupleList):
            self.tupleList = tupleList
    def __getattr__(self, name):
            return self.tupleList.index(name)



Keep it simple when using Python 3:

from enum import Enum
class MyEnum(Enum):
    UP = 1
    DOWN = 2
    LEFT = 3
    RIGHT = 4



See: https://docs.python.org/3/library/enum.html

  • Does this have an advantage over enum.Enum? Or is this just an answer that should be deleted, not that Python 3.6 is already deprecated and Python 3.4 introduced the built-in enum package? Jan 21, 2022 at 8:12
  • @MartinThoma Yes, this is from years ago. When you use Python 3. I definitely advice you to use the built-in Enum: docs.python.org/3/library/enum.html Jan 21, 2022 at 20:06

From Python 3.4 there is official support for enums. You can find documentation and examples here on Python 3.4 documentation page.

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
  • Back porting is now supported as well. This is the way to go.
    – srock
    Jun 10, 2014 at 19:10

Another, very simple, implementation of an enum in Python, using namedtuple:

from collections import namedtuple

def enum(*keys):
    return namedtuple('Enum', keys)(*keys)

MyEnum = enum('FOO', 'BAR', 'BAZ')

or, alternatively,

# With sequential number values
def enum(*keys):
    return namedtuple('Enum', keys)(*range(len(keys)))

# From a dict / keyword args
def enum(**kwargs):
    return namedtuple('Enum', kwargs.keys())(*kwargs.values())

# Example for dictionary param:
values = {"Salad": 20, "Carrot": 99, "Tomato": "No i'm not"} 
Vegetables= enum(**values)

# >>> print(Vegetables.Tomato)        'No i'm not'

# Example for keyworded params: 
Fruits = enum(Apple="Steve Jobs", Peach=1, Banana=2)

# >>> print(Fruits.Apple)             'Steve Jobs'

Like the method above that subclasses set, this allows:

'FOO' in MyEnum
other = MyEnum.FOO
assert other == MyEnum.FOO

But has more flexibility as it can have different keys and values. This allows

MyEnum.FOO < MyEnum.BAR

to act as is expected if you use the version that fills in sequential number values.

  • I liked this approach the most because is easy and clear. One note for who is willing to use it.. The collections module is going to move into collections.abc in Python 3.10. This module does not seem to include namedtuple, so it could be possible that namedtuplestays inside the collections module Jul 22, 2020 at 9:15
  • I have no idea how is the named tuple "enum" is supposed to work... It's a tuple, not an enum, it has as many fields as the "enum" has values, and those fields all have string values... how does one even use it?? Feb 23, 2021 at 19:17
  • @Kubahasn'tforgottenMonica I don't really understand what you're asking. What is it you don't see how to do? I cover the basics in the answer.
    – agf
    Feb 24, 2021 at 0:52

Hmmm... I suppose the closest thing to an enum would be a dictionary, defined either like this:

months = {
    'January': 1,
    'February': 2,


months = dict(

Then, you can use the symbolic name for the constants like this:

mymonth = months['January']

There are other options, like a list of tuples, or a tuple of tuples, but the dictionary is the only one that provides you with a "symbolic" (constant string) way to access the value.

Edit: I like Alexandru's answer too!

  • And most of all you can easily iterate on a dictionary if you need to access its values like you need its string values to appear as combo box items. So use a dictionary as a replacement for enumerations instead. Feb 12, 2012 at 17:32

What I use:

class Enum(object):
    def __init__(self, names, separator=None):
        self.names = names.split(separator)
        for value, name in enumerate(self.names):
            setattr(self, name.upper(), value)
    def tuples(self):
        return tuple(enumerate(self.names))

How to use:

>>> state = Enum('draft published retracted')
>>> state.DRAFT
>>> state.RETRACTED
>>> state.FOO
Traceback (most recent call last):
   File "<stdin>", line 1, in <module>
AttributeError: 'Enum' object has no attribute 'FOO'
>>> state.tuples()
((0, 'draft'), (1, 'published'), (2, 'retracted'))

So this gives you integer constants like state.PUBLISHED and the two-tuples to use as choices in Django models.


The standard in Python is PEP 435, so an Enum class is available in Python 3.4+:

>>> from enum import Enum
>>> class Colors(Enum):
...     red = 1
...     green = 2
...     blue = 3
>>> for color in Colors: print color

davidg recommends using dicts. I'd go one step further and use sets:

months = set('January', 'February', ..., 'December')

Now you can test whether a value matches one of the values in the set like this:

if m in months:

like dF, though, I usually just use string constants in place of enums.

  • yep!, much better if u inherit set and provide getattr method !
    – shahjapan
    May 11, 2010 at 3:10

This is the best one I have seen: "First Class Enums in Python"


It gives you a class, and the class contains all the enums. The enums can be compared to each other, but don't have any particular value; you can't use them as an integer value. (I resisted this at first because I am used to C enums, which are integer values. But if you can't use it as an integer, you can't use it as an integer by mistake so overall I think it is a win.) Each enum is a unique value. You can print enums, you can iterate over them, you can test that an enum value is "in" the enum. It's pretty complete and slick.

Edit (cfi): The above link is not Python 3 compatible. Here's my port of enum.py to Python 3:

def cmp(a,b):
   if a < b: return -1
   if b < a: return 1
   return 0

def Enum(*names):
   ##assert names, "Empty enums are not supported" # <- Don't like empty enums? Uncomment!

   class EnumClass(object):
      __slots__ = names
      def __iter__(self):        return iter(constants)
      def __len__(self):         return len(constants)
      def __getitem__(self, i):  return constants[i]
      def __repr__(self):        return 'Enum' + str(names)
      def __str__(self):         return 'enum ' + str(constants)

   class EnumValue(object):
      __slots__ = ('__value')
      def __init__(self, value): self.__value = value
      Value = property(lambda self: self.__value)
      EnumType = property(lambda self: EnumType)
      def __hash__(self):        return hash(self.__value)
      def __cmp__(self, other):
         # C fans might want to remove the following assertion
         # to make all enums comparable by ordinal value {;))
         assert self.EnumType is other.EnumType, "Only values from the same enum are comparable"
         return cmp(self.__value, other.__value)
      def __lt__(self, other):   return self.__cmp__(other) < 0
      def __eq__(self, other):   return self.__cmp__(other) == 0
      def __invert__(self):      return constants[maximum - self.__value]
      def __nonzero__(self):     return bool(self.__value)
      def __repr__(self):        return str(names[self.__value])

   maximum = len(names) - 1
   constants = [None] * len(names)
   for i, each in enumerate(names):
      val = EnumValue(i)
      setattr(EnumClass, each, val)
      constants[i] = val
   constants = tuple(constants)
   EnumType = EnumClass()
   return EnumType

if __name__ == '__main__':
   print( '\n*** Enum Demo ***')
   print( '--- Days of week ---')
   Days = Enum('Mo', 'Tu', 'We', 'Th', 'Fr', 'Sa', 'Su')
   print( Days)
   print( Days.Mo)
   print( Days.Fr)
   print( Days.Mo < Days.Fr)
   print( list(Days))
   for each in Days:
      print( 'Day:', each)
   print( '--- Yes/No ---')
   Confirmation = Enum('No', 'Yes')
   answer = Confirmation.No
   print( 'Your answer is not', ~answer)
  • This recipe was used as the basis for a PEP, which was rejected. python.org/dev/peps/pep-0354 One extension that I like: enum values should have a member variable that lets you get the internal integer value out. It shouldn't be possible to cast an enum to an integer by mistake, so the .__int__() method should raise an exception for an enum; but there should be a way to get the value out. And it should be possible to set specific integer values in at class definition time, so you could use an enum for things like the constants in the stat module.
    – steveha
    Mar 21, 2012 at 22:41

I have had occasion to need of an Enum class, for the purpose of decoding a binary file format. The features I happened to want is concise enum definition, the ability to freely create instances of the enum by either integer value or string, and a useful representation. Here's what I ended up with:

>>> class Enum(int):
...     def __new__(cls, value):
...         if isinstance(value, str):
...             return getattr(cls, value)
...         elif isinstance(value, int):
...             return cls.__index[value]
...     def __str__(self): return self.__name
...     def __repr__(self): return "%s.%s" % (type(self).__name__, self.__name)
...     class __metaclass__(type):
...         def __new__(mcls, name, bases, attrs):
...             attrs['__slots__'] = ['_Enum__name']
...             cls = type.__new__(mcls, name, bases, attrs)
...             cls._Enum__index = _index = {}
...             for base in reversed(bases):
...                 if hasattr(base, '_Enum__index'):
...                     _index.update(base._Enum__index)
...             # create all of the instances of the new class
...             for attr in attrs.keys():
...                 value = attrs[attr]
...                 if isinstance(value, int):
...                     evalue = int.__new__(cls, value)
...                     evalue._Enum__name = attr
...                     _index[value] = evalue
...                     setattr(cls, attr, evalue)
...             return cls

A whimsical example of using it:

>>> class Citrus(Enum):
...     Lemon = 1
...     Lime = 2
>>> Citrus.Lemon
>>> Citrus(1)
>>> Citrus(5)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
  File "<stdin>", line 6, in __new__
KeyError: 5
>>> class Fruit(Citrus):
...     Apple = 3
...     Banana = 4
>>> Fruit.Apple
>>> Fruit.Lemon
>>> Fruit(1)
>>> Fruit(3)
>>> "%d %s %r" % ((Fruit.Apple,)*3)
'3 Apple Fruit.Apple'
>>> Fruit(1) is Citrus.Lemon

Key features:

  • str(), int() and repr() all produce the most useful output possible, respectively the name of the enumartion, its integer value, and a Python expression that evaluates back to the enumeration.
  • Enumerated values returned by the constructor are limited strictly to the predefined values, no accidental enum values.
  • Enumerated values are singletons; they can be strictly compared with is
  • I really like the use of a superclass with its own metaclass, to make it easy to define enums. What's missing here is a __contains__ method. I'd like to be able to check that a given variable is part of the enum - mostly because I want the enums for allowable values of a function parameter.
    – xorsyst
    Aug 2, 2012 at 9:37
  • This is actually a slightly trimmed version of the one I originally created (which you can find here: enum_strict.py )v which defines a __instancecheck__ method. Classes are not collections of instances, so 1 in Fruit is absurd. However, the linked version supports isinstance(1, Fruit) which would be more correct in terms of the notion of classes and instances. Aug 2, 2012 at 11:30
  • But forgetting classes and thinking in terms of enums, then it makes sense to think of them as a collection. For example, I might have an enum of file opening modes (MODE.OPEN, MODE.WRITE, etc). I want to verify the parameters to my function: if mode in MODE: reads a lot better than isintance(mode, Mode)
    – xorsyst
    Aug 6, 2012 at 10:11
  • I have put up something very similar, which supports more than just ints, and is documented and tested, on GitHub: github.com/hmeine/named_constants
    – hans_meine
    Jan 18, 2017 at 8:47

For old Python 2.x

def enum(*sequential, **named):
    enums = dict(zip(sequential, [object() for _ in range(len(sequential))]), **named)
    return type('Enum', (), enums)

If you name it, is your problem, but if not creating objects instead of values allows you to do this:

>>> DOG = enum('BARK', 'WALK', 'SIT')
>>> CAT = enum('MEOW', 'WALK', 'SIT')

When using other implementations sited here (also when using named instances in my example) you must be sure you never try to compare objects from different enums. For here's a possible pitfall:

>>> DOG = enum('BARK'=1, 'WALK'=2, 'SIT'=3)
>>> CAT = enum('WALK'=1, 'SIT'=2)
>>> pet1_state = DOG.BARK
>>> pet2_state = CAT.WALK
>>> pet1_state == pet2_state


  • Does this have an advantage over enum.Enum? Or is this just an answer that should be deleted, not that Python 3.6 is already deprecated and Python 3.4 introduced the built-in enum package? Jan 21, 2022 at 8:12
  • @MartinThoma I've updated the info, since this was meant for python 2.x
    – estani
    Jan 24, 2022 at 15:43

I really like Alec Thomas' solution (http://stackoverflow.com/a/1695250):

def enum(**enums):
    '''simple constant "enums"'''
    return type('Enum', (object,), enums)

It's elegant and clean looking, but it's just a function that creates a class with the specified attributes.

With a little modification to the function, we can get it to act a little more 'enumy':

NOTE: I created the following examples by trying to reproduce the behavior of pygtk's new style 'enums' (like Gtk.MessageType.WARNING)

def enum_base(t, **enums):
    '''enums with a base class'''
    T = type('Enum', (t,), {})
    for key,val in enums.items():
        setattr(T, key, T(val))

    return T

This creates an enum based off a specified type. In addition to giving attribute access like the previous function, it behaves as you would expect an Enum to with respect to types. It also inherits the base class.

For example, integer enums:

>>> Numbers = enum_base(int, ONE=1, TWO=2, THREE=3)
>>> Numbers.ONE
>>> x = Numbers.TWO
>>> 10 + x
>>> type(Numbers)
<type 'type'>
>>> type(Numbers.ONE)
<class 'Enum'>
>>> isinstance(x, Numbers)

Another interesting thing that can be done with this method is customize specific behavior by overriding built-in methods:

def enum_repr(t, **enums):
    '''enums with a base class and repr() output'''
    class Enum(t):
        def __repr__(self):
            return '<enum {0} of type Enum({1})>'.format(self._name, t.__name__)

    for key,val in enums.items():
        i = Enum(val)
        i._name = key
        setattr(Enum, key, i)

    return Enum

>>> Numbers = enum_repr(int, ONE=1, TWO=2, THREE=3)
>>> repr(Numbers.ONE)
'<enum ONE of type Enum(int)>'
>>> str(Numbers.ONE)

The enum package from PyPI provides a robust implementation of enums. An earlier answer mentioned PEP 354; this was rejected but the proposal was implemented http://pypi.python.org/pypi/enum.

Usage is easy and elegant:

>>> from enum import Enum
>>> Colors = Enum('red', 'blue', 'green')
>>> shirt_color = Colors.green
>>> shirt_color = Colors[2]
>>> shirt_color > Colors.red
>>> shirt_color.index
>>> str(shirt_color)

Here's an approach with some different characteristics I find valuable:

  • allows > and < comparison based on order in enum, not lexical order
  • can address item by name, property or index: x.a, x['a'] or x[0]
  • supports slicing operations like [:] or [-1]

and most importantly prevents comparisons between enums of different types!

Based closely on http://code.activestate.com/recipes/413486-first-class-enums-in-python.

Many doctests included here to illustrate what's different about this approach.

def enum(*names):
    Well-behaved enumerated type, easier than creating custom classes

    Create a custom type that implements an enumeration.  Similar in concept
    to a C enum but with some additional capabilities and protections.  See

    names       Ordered list of names.  The order in which names are given
                will be the sort order in the enum type.  Duplicate names
                are not allowed.  Unicode names are mapped to ASCII.

    Object of type enum, with the input names and the enumerated values.

    >>> letters = enum('a','e','i','o','u','b','c','y','z')
    >>> letters.a < letters.e

    ## index by property
    >>> letters.a

    ## index by position
    >>> letters[0]

    ## index by name, helpful for bridging string inputs to enum
    >>> letters['a']

    ## sorting by order in the enum() create, not character value
    >>> letters.u < letters.b

    ## normal slicing operations available
    >>> letters[-1]

    ## error since there are not 100 items in enum
    >>> letters[99]
    Traceback (most recent call last):
    IndexError: tuple index out of range

    ## error since name does not exist in enum
    >>> letters['ggg']
    Traceback (most recent call last):
    ValueError: tuple.index(x): x not in tuple

    ## enums must be named using valid Python identifiers
    >>> numbers = enum(1,2,3,4)
    Traceback (most recent call last):
    AssertionError: Enum values must be string or unicode

    >>> a = enum('-a','-b')
    Traceback (most recent call last):
    TypeError: Error when calling the metaclass bases
        __slots__ must be identifiers

    ## create another enum
    >>> tags = enum('a','b','c')
    >>> tags.a
    >>> letters.a

    ## can't compare values from different enums
    >>> letters.a == tags.a
    Traceback (most recent call last):
    AssertionError: Only values from the same enum are comparable

    >>> letters.a < tags.a
    Traceback (most recent call last):
    AssertionError: Only values from the same enum are comparable

    ## can't update enum after create
    >>> letters.a = 'x'
    Traceback (most recent call last):
    AttributeError: 'EnumClass' object attribute 'a' is read-only

    ## can't update enum after create
    >>> del letters.u
    Traceback (most recent call last):
    AttributeError: 'EnumClass' object attribute 'u' is read-only

    ## can't have non-unique enum values
    >>> x = enum('a','b','c','a')
    Traceback (most recent call last):
    AssertionError: Enums must not repeat values

    ## can't have zero enum values
    >>> x = enum()
    Traceback (most recent call last):
    AssertionError: Empty enums are not supported

    ## can't have enum values that look like special function names
    ## since these could collide and lead to non-obvious errors
    >>> x = enum('a','b','c','__cmp__')
    Traceback (most recent call last):
    AssertionError: Enum values beginning with __ are not supported

    Enum values of unicode type are not preserved, mapped to ASCII instead.

    ## must have at least one enum value
    assert names, 'Empty enums are not supported'
    ## enum values must be strings
    assert len([i for i in names if not isinstance(i, types.StringTypes) and not \
        isinstance(i, unicode)]) == 0, 'Enum values must be string or unicode'
    ## enum values must not collide with special function names
    assert len([i for i in names if i.startswith("__")]) == 0,\
        'Enum values beginning with __ are not supported'
    ## each enum value must be unique from all others
    assert names == uniquify(names), 'Enums must not repeat values'

    class EnumClass(object):
        """ See parent function for explanation """

        __slots__ = names

        def __iter__(self):
            return iter(constants)

        def __len__(self):
            return len(constants)

        def __getitem__(self, i):
            ## this makes xx['name'] possible
            if isinstance(i, types.StringTypes):
                i = names.index(i)
            ## handles the more normal xx[0]
            return constants[i]

        def __repr__(self):
            return 'enum' + str(names)

        def __str__(self):
            return 'enum ' + str(constants)

        def index(self, i):
            return names.index(i)

    class EnumValue(object):
        """ See parent function for explanation """

        __slots__ = ('__value')

        def __init__(self, value):
            self.__value = value

        value = property(lambda self: self.__value)

        enumtype = property(lambda self: enumtype)

        def __hash__(self):
            return hash(self.__value)

        def __cmp__(self, other):
            assert self.enumtype is other.enumtype, 'Only values from the same enum are comparable'
            return cmp(self.value, other.value)

        def __invert__(self):
            return constants[maximum - self.value]

        def __nonzero__(self):
            ## return bool(self.value)
            ## Original code led to bool(x[0])==False, not correct
            return True

        def __repr__(self):
            return str(names[self.value])

    maximum = len(names) - 1
    constants = [None] * len(names)
    for i, each in enumerate(names):
        val = EnumValue(i)
        setattr(EnumClass, each, val)
        constants[i] = val
    constants = tuple(constants)
    enumtype = EnumClass()
    return enumtype

Alexandru's suggestion of using class constants for enums works quite well.

I also like to add a dictionary for each set of constants to lookup a human-readable string representation.

This serves two purposes: a) it provides a simple way to pretty-print your enum and b) the dictionary logically groups the constants so that you can test for membership.

class Animal:    
  TYPE_DOG = 1
  TYPE_CAT = 2

  type2str = {
    TYPE_DOG: "dog",
    TYPE_CAT: "cat"

  def __init__(self, type_):
    assert type_ in self.type2str.keys()
    self._type = type_

  def __repr__(self):
    return "<%s type=%s>" % (
        self.__class__.__name__, self.type2str[self._type].upper())

While the original enum proposal, PEP 354, was rejected years ago, it keeps coming back up. Some kind of enum was intended to be added to 3.2, but it got pushed back to 3.3 and then forgotten. And now there's a PEP 435 intended for inclusion in Python 3.4. The reference implementation of PEP 435 is flufl.enum.

As of April 2013, there seems to be a general consensus that something should be added to the standard library in 3.4—as long as people can agree on what that "something" should be. That's the hard part. See the threads starting here and here, and a half dozen other threads in the early months of 2013.

Meanwhile, every time this comes up, a slew of new designs and implementations appear on PyPI, ActiveState, etc., so if you don't like the FLUFL design, try a PyPI search.


Here is a nice Python recipe that I found here: http://code.activestate.com/recipes/577024-yet-another-enum-for-python/

def enum(typename, field_names):
    "Create a new enumeration type"

    if isinstance(field_names, str):
        field_names = field_names.replace(',', ' ').split()
    d = dict((reversed(nv) for nv in enumerate(field_names)), __slots__ = ())
    return type(typename, (object,), d)()

Example Usage:


More details can be found on the recipe page.

  • Does this have an advantage over enum.Enum? Or is this just an answer that should be deleted, not that Python 3.6 is already deprecated and Python 3.4 introduced the built-in enum package? Jan 21, 2022 at 8:12

Here is a variant on Alec Thomas's solution:

def enum(*args, **kwargs):
    return type('Enum', (), dict((y, x) for x, y in enumerate(args), **kwargs)) 

x = enum('POOH', 'TIGGER', 'EEYORE', 'ROO', 'PIGLET', 'RABBIT', 'OWL')
assert x.POOH == 0
assert x.TIGGER == 1
  • Any way that does not need to use ""? Apr 15, 2021 at 13:57

This solution is a simple way of getting a class for the enumeration defined as a list (no more annoying integer assignments):


import new

def create(class_name, names):
    return new.classobj(
        class_name, (object,), dict((y, x) for x, y in enumerate(names))


import enumeration

Colors = enumeration.create('Colors', (
  • 2
    This is a really old-timey way to create classes. Why not simply use type(class_name, (object,), dict(...)) instead?
    – terminus
    Jan 1, 2012 at 17:32

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