I have a situation where I need to enforce and give the user the option of one of a number of select functions, to be passed in as an argument to another function:

I really want to achieve something like the following:

from enum import Enum

#Trivial Function 1
def functionA():

#Trivial Function 2
def functionB():

#This is not allowed (as far as i can tell the values should be integers)
#But pseudocode for what I am after
class AvailableFunctions(Enum):
    OptionA = functionA
    OptionB = functionB

So the following can be executed:

def myUserFunction(theFunction = AvailableFunctions.OptionA):
   #Type Check
   assert isinstance(theFunction,AvailableFunctions) 

   #Execute the actual function held as value in the enum or equivalent
   return theFunction.value() 
  • Another option: put the functions in a dict, with the function name as the key.
    – PM 2Ring
    Oct 31, 2016 at 8:30
  • You discovered the edge case of enums... when python builds a class it adds the functional attributes as methods of the class. That's why they don't end up as values of the Enum. As I show in my answer it is easy to "fool" the interpreter into not making those as methods.
    – Bakuriu
    Oct 31, 2016 at 9:36

6 Answers 6


Your assumption is wrong. Values can be arbitrary, they are not limited to integers. From the documentation:

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.

However the issue with functions is that they are considered to be method definitions instead of attributes!

In [1]: from enum import Enum

In [2]: def f(self, *args):
   ...:     pass

In [3]: class MyEnum(Enum):
   ...:     a = f
   ...:     def b(self, *args):
   ...:         print(self, args)

In [4]: list(MyEnum)  # it has no values
Out[4]: []

In [5]: MyEnum.a
Out[5]: <function __main__.f>

In [6]: MyEnum.b
Out[6]: <function __main__.MyEnum.b>

You can work around this by using a wrapper class or just functools.partial or (only in Python2) staticmethod:

from functools import partial

class MyEnum(Enum):
    OptionA = partial(functionA)
    OptionB = staticmethod(functionB)

Sample run:

In [7]: from functools import partial

In [8]: class MyEnum2(Enum):
   ...:     a = partial(f)
   ...:     def b(self, *args):
   ...:         print(self, args)

In [9]: list(MyEnum2)
Out[9]: [<MyEnum2.a: functools.partial(<function f at 0x7f4130f9aae8>)>]

In [10]: MyEnum2.a
Out[10]: <MyEnum2.a: functools.partial(<function f at 0x7f4130f9aae8>)>

Or using a wrapper class:

In [13]: class Wrapper:
    ...:     def __init__(self, f):
    ...:         self.f = f
    ...:     def __call__(self, *args, **kwargs):
    ...:         return self.f(*args, **kwargs)

In [14]: class MyEnum3(Enum):
    ...:     a = Wrapper(f)

In [15]: list(MyEnum3)
Out[15]: [<MyEnum3.a: <__main__.Wrapper object at 0x7f413075b358>>]

Also note that if you want you can define the __call__ method in your enumeration class to make the values callable:

In [1]: from enum import Enum

In [2]: def f(*args):
   ...:     print(args)

In [3]: class MyEnum(Enum):
   ...:     a = partial(f)
   ...:     def __call__(self, *args):
   ...:         self.value(*args)

In [5]: MyEnum.a(1,2,3)   # no need for MyEnum.a.value(1,2,3)
(1, 2, 3)
  • 1
    Note that the __call__ method should contain a return statement or else when you call the functions, you won't get the intended response. I was stuck on that for 2 hours. Seems obvious in hindsight, but in case someone else gets stuck here...
    – Logister
    Feb 29, 2020 at 20:41
  • @Logister Only if the functions return a value.
    – Bakuriu
    Mar 1, 2020 at 9:57
  • 3
    No need to import partial, btw, you can just do a = staticmethod(f) instead.
    – mar77i
    Mar 17, 2020 at 21:35
  • 1
    @mar77i That's right. I've edited the answer to also show that option. Thanks.
    – Bakuriu
    Mar 21, 2020 at 10:46
  • I did not get staticmethod to work, however, functools.partial worked flawlessly. Thank you for this clever solution! Jun 1, 2020 at 17:51

Since Python 3.11 there is much more concise and understandable way. member and nonmember functions were added to enum among other improvements, so you can now do the following:

from enum import Enum, member, nonmember

def fn(x):

class MyEnum(Enum):
    x = nonmember(1)
    meth = fn
    mem = member(fn)
    def this_is_a_method(cls):
        print('No, still not a member')
    def this_is_just_function():
        print('No, not a member')
    def this_is_a_member(x):
        print('Now a member!', x)

And now

>>> list(MyEnum)
[<MyEnum.mem: <function fn at ...>>, <MyEnum.this_is_a_member: <function MyEnum.this_is_a_member at ...>>]

>>> MyEnum.meth(1)

>>> MyEnum.mem(1)
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: 'MyEnum' object is not callable

>>> MyEnum.mem.value(1)

>>> MyEnum.this_is_a_method()
No, still not a member

>>> MyEnum.this_is_just_function()
No, not a member

>>> MyEnum.this_is_a_member()
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: 'MyEnum' object is not callable

>>> MyEnum.this_is_a_member.value(1)
Now a member! 1

>>> MyEnum.x

Of course, you can add __call__ to avoid explicit .value calls:

class MyEnum(Enum):
    def __call__(self, *args, **kwargs):
        return self.value(*args, **kwargs)

and now

>>> MyEnum.mem(1)

Note that this cannot be typed correctly unless all your enum member functions share the same signature.


Another less clunky solution is to put the functions in a tuple. As Bakuriu mentioned, you may want to make the enum callable.

from enum import Enum

def functionA():

def functionB():

class AvailableFunctions(Enum):
    OptionA = (functionA,)
    OptionB = (functionB,)

    def __call__(self, *args, **kwargs):
        self.value[0](*args, **kwargs)

Now you can use it like this:

AvailableFunctions.OptionA() # calls functionA

In addition to the answer of Bakuriu... If you use the wrapper approach like above you loose information about the original function like __name__, __repr__ and so on after wrapping it. This will cause problems for example if you want to use sphinx for generation of source code documentation. Therefore add the following to your wrapper class.

class wrapper:
    def __init__(self, function):
        self.function = function
        functools.update_wrapper(self, function)
    def __call__(self,*args, **kwargs):
        return self.function(*args, **kwargs)
    def __repr__(self):
        return self.function.__repr__()

Building on top of @bakuriu's approach, I just want to highlight that we can also use dictionaries of multiple functions as values and have a broader polymorphism, similar to enums in Java. Here is a fictitious example to show what I mean:

from enum import Enum, unique

class MyEnum(Enum):
    test = {'execute': lambda o: o.test()}
    prod = {'execute': lambda o: o.prod()}

    def __getattr__(self, name):
        if name in self.__dict__:
            return self.__dict__[name]
        elif not name.startswith("_"):
            value = self.__dict__['_value_']
            return value[name]
        raise AttributeError(name)

class Executor:
    def __init__(self, mode: MyEnum):
        self.mode = mode

    def test(self):
        print('test run')

    def prod(self):
        print('prod run')

    def execute(self):


Obviously, the dictionary approach provides no additional benefit when there is only a single function, so use this approach when there are multiple functions. Ensure that the keys are uniform across all values as otherwise, the usage won't be polymorphic.

The __getattr__ method is optional, it is only there for syntactic sugar (i.e., without it, mode.execute() would become mode.value['execute']().

Since dictionaries can't be made readonly, using namedtuple would be better and require only minor changes to the above.

from enum import Enum, unique
from collections import namedtuple

EnumType = namedtuple("EnumType", "execute")

class MyEnum(Enum):
    test = EnumType(lambda o: o.test())
    prod = EnumType(lambda o: o.prod())

    def __getattr__(self, name):
        if name in self.__dict__:
            return self.__dict__[name]
        elif not name.startswith("_"):
            value = self.__dict__['_value_']
            return getattr(value, name)
        raise AttributeError(name)
  • I just understood what syntactic sugar is thanks to your example, thank you. Jun 18, 2022 at 17:52

Just to add to this: there a way to make it work without partial or member in downstream code, but you have to go deep into metaclasses and the implementation of Enum. Building on the other answers, this works:

from enum import Enum, EnumType, _EnumDict, member
import inspect

class _ExtendedEnumType(EnumType):
    # Autowraps class-level functions/lambdas in enum with member, so they behave as one would expect
    # I.e. be a member with name and value instead of becoming a method
    # This is a hack, going deep into the internals of the enum class
    # and performing an open-heart surgery on it...
    def __new__(metacls, cls: str, bases, classdict: _EnumDict, *, boundary=None, _simple=False, **kwds):
        non_members = set(classdict).difference(classdict._member_names)
        for k in non_members:
            if not k.startswith("_"):
                if classdict[k].__class__ in [classmethod, staticmethod]:
                # instance methods don't make sense for enums, and may break callable enums
                if "self" in inspect.signature(classdict[k]).parameters:
                    raise TypeError(
                        f"Instance methods are not allowed in enums but found method"
                        f" {classdict[k]} in {cls}"
                # After all the input validation, we can finally wrap the function
                # For python<3.11, one should use `functools.partial` instead of `member`
                callable_val = member(classdict[k])
                # We have to use del since _EnumDict doesn't allow overwriting
                del classdict[k]
                classdict[k] = callable_val
                classdict._member_names[k] = None
        return super().__new__(metacls, cls, bases, classdict, boundary=boundary, _simple=_simple, **kwds)

class ExtendedEnum(Enum, metaclass=_ExtendedEnumType):

Now you can do:

class A(ExtendedEnum):
    a = 3
    b = lambda: 4
    def afunc(cls):
        return 5
    def bfunc():

Everything will work as expected.

PS: For some more Enum magic, I also like to add

    def __getitem__(cls, item):
        if hasattr(item, "name"):
            item = item.name
        # can't use [] because of particularities of super()
        return super().__getitem__(item)

to _ExtendedEnumType, so that A[A.a] works.

And I also recommend to make the callable enum, as proposed above.


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