82

I have a function which validates its argument to accept only values from a given list of valid options. Typing-wise, I reflect this behavior using a Literal type alias, like so:

from typing import Literal


VALID_ARGUMENTS = ['foo', 'bar']

Argument = Literal['foo', 'bar']


def func(argument: 'Argument') -> None:
    if argument not in VALID_ARGUMENTS:
        raise ValueError(
            f'argument must be one of {VALID_ARGUMENTS}'
        )
    # ...

This is a violation of the DRY principle, because I have to rewrite the list of valid arguments in the definition of my Literal type, even if it is already stored in the variable VALID_ARGUMENTS. How can I create the Argument Literal type dynamically, given the VALID_ARGUMENTS variable?

The following things do not work:

from typing import Literal, Union, NewType


Argument = Literal[*VALID_ARGUMENTS]  # SyntaxError: invalid syntax

Argument = Literal[VALID_ARGUMENTS]  # Parameters to generic types must be types

Argument = Literal[Union[VALID_ARGUMENTS]]  # TypeError: Union[arg, ...]: each arg must be a type. Got ['foo', 'bar'].

Argument = NewType(
    'Argument',
    Union[
        Literal[valid_argument]
        for valid_argument in VALID_ARGUMENTS
    ]
)  # Expected type 'Type[_T]', got 'list' instead

Can it be done at all?

2
  • 4
    You almost got it! Literal accept a tuple of types or literals. ValidArgs = Literal[tuple(VALID_ARGUMENTS)] will work. But as was mentioned already it defeats static type checkers.
    – kuza
    Dec 2, 2020 at 19:43
  • 3
    Of course it defeats static type checkers. The goal here is a contradiction in terms. Creating the type dynamically means that it can't happen until the code runs. The entire point of a static type checker is that it performs its checks before the code runs. Aug 23, 2023 at 2:52

5 Answers 5

84

Go the other way around, and build VALID_ARGUMENTS from Argument:

Argument = typing.Literal['foo', 'bar']
VALID_ARGUMENTS: typing.Tuple[Argument, ...] = typing.get_args(Argument)

I've used a tuple for VALID_ARGUMENTS here, but if for some reason you really prefer a list, you can get one:

VALID_ARGUMENTS: typing.List[Argument] = list(typing.get_args(Argument))

It's possible at runtime to build Argument from VALID_ARGUMENTS, but doing so is incompatible with static analysis, which is the primary use case of type annotations.

Doing so is also considered semantically invalid - the spec forbids parameterizing Literal with dynamically computed parameters. The runtime implementation simply doesn't have the information it would need to validate this. Building VALID_ARGUMENTS from Argument is the way to go.

4
  • 3
    What is the purpose of the ellipsis intyping.Tuple[Argument, ...]?
    – N4v
    Sep 28, 2021 at 15:09
  • 14
    @N4v: That's the syntax for a homogeneous, arbitrary-length tuple. Sep 29, 2021 at 0:46
  • This is a good way to go but you lose type information. If you do VALID_ARGUMENTS = "foo", "bar" by hand you get tuple[Literal["foo"], Literal["bar"]] instead of tuple[Argument, ...], so I think the best way is still rewriting everything by hand a second time
    – Fayeure
    Aug 17, 2023 at 8:33
  • 1
    @Fayeure: Perhaps, but it's hard to come up with a reasonable use case where something should actually care about the extra type information. It'd have to be something that statically relies on the order of VALID_ARGUMENTS, and relying on the order at all, let alone statically, seems like a bad idea. Aug 17, 2023 at 8:42
36

If anyone's still looking for a workaround for this:

typing.Literal[tuple(VALID_ARGUMENTS)]
7
  • 18
    From the mypy documentation: "Literal types may contain one or more literal bools, ints, strs, bytes, and enum values. However, literal types cannot contain arbitrary expressions: types like Literal[my_string.trim()], Literal[x > 3], or Literal[3j + 4] are all illegal." So this is valid python syntax, but will not be understood by any type checker, which completely defies the point of adding type hints in the first place. mypy.readthedocs.io/en/stable/literal_types.html#limitations Sep 2, 2021 at 21:10
  • 7
    Absolutely doens't defeat the purpose. Typing can be viewed as, in first instance, structured documentation. This absolutely solves that problem.
    – Marc
    Dec 7, 2021 at 23:14
  • 1
    @alex-waygood there are frameworks that use type hints as well. For example, in order to semi-dynamically include a list of allowed values in your FastAPI swagger UI/documentation, this is pretty much the only way at the moment. It's not nice but it's better than hard coding the values in some cases.
    – miksus
    May 22, 2022 at 16:38
  • 4
    I can't edit my comment, but sure, I agree that if you're using type hints for runtime purposes rather than for static typing, this can still be useful. I feel like it's fair enough to assume, however, in the context of a question regarding Python typing, that the author is looking for a solution that will please static type-checkers, unless otherwise stated. By far the most common use for type hints is for static type-checking. May 22, 2022 at 17:46
  • 3
    Does this still work? I get Type arguments for "Literal" must be None, a literal value (int, bool, str, or bytes), or an enum value [Pylance]
    – Gerrat
    Sep 28, 2023 at 12:20
3

Expanding on @user2357112's answer... it's possible to make variables for the individual strings of "foo" and "bar".

from __future__ import annotations
from typing import get_args, Literal, TypeAlias

T_foo = Literal['foo']
T_bar = Literal['bar']
T_valid_arguments: TypeAlias = T_foo | T_bar

FOO: T_foo = get_args(T_foo)[0]
BAR: T_bar = get_args(T_bar)[0]

VALID_ARGUMENTS = (FOO, BAR)


def func(argument: T_valid_arguments) -> None:
    if argument not in VALID_ARGUMENTS:
        raise ValueError(f"argument must be one of {VALID_ARGUMENTS}")


#mypy checks
func(FOO)  # OK
func('foo')  # OK
func('baz')  # error: Argument 1 to "func" has incompatible type "Literal['baz']"; expected "Literal['foo', 'bar']"  [arg-type]

reveal_type(FOO) # note: Revealed type is "Literal['foo']" 
reveal_type(BAR). # note: Revealed type is "Literal['bar']"
reveal_type(VALID_ARGUMENTS)  # note: Revealed type is "tuple[Literal['foo'], Literal['bar']]"

Though, it could be argued that using get_args in this case is overkill to avoid typing the string "foo" twice in code. (re: DRY vs WET) You could just as easily do the following with the same results.

from __future__ import annotations
from typing import Literal, TypeAlias

T_foo = Literal['foo']
T_bar = Literal['bar']
T_valid_arguments: TypeAlias = T_foo | T_bar

FOO: T_foo = 'foo'
BAR: T_bar = 'bar'

VALID_ARGUMENTS = (FOO, BAR)

As a word of caution with using Literal strings as annotations. Mypy will complain about this:

FOO = 'foo'

def func(argument: T_valid_arguments) -> None:
    ...

func(FOO) #  error: Argument 1 to "func" has incompatible type "str"; expected "Literal['foo', 'bar']"  [arg-type]

But the following is fine.

func('foo')  # OK
1

It seems that the python authorities have realized that indeed the feature is useful, and since 3.11 we can use variadics in Literal:

from typing import Literal, Any
from inspect import signature

def foo(snap: int, crackle: str = 'hello', pop: float = 3.14) -> None:
    pass

valid_values = list(signature(foo).parameters)
FooArgname = Literal[*valid_values]
assert FooArgname == Literal['snap', 'crackle', 'pop']

# example usage: making a type for valid kwargs for foo
ValidFooKwargs = dict[FooArgname, Any]

The use of being able to define the list of valid values "dynamically" should be obvious in the example above: We want to have a FooArgname type that is aligned with an object (here foo). When we had to define this list "statically", we were not DRY and risked misalignment with the target object.

The Literal[tuple(valid_values)] solution mentioned by Chris Goddard above executes without a syntax error, but my linter complains in red still (when running 3.10).

Appendix

For completeness, since the first comment references my original code, here it is:

from typing import Literal
from inspect import signature, Parameter

valid_values = list(signature(Parameter).parameters)

ParamAttribute = Literal[*valid_values]
assert ParamAttribute == Literal['name', 'kind', 'default', 'annotation']
6
  • 1
    Oh, that is nice. Thanks for keeping the answers up to date with the development! I think your example would become more instructive if you use a custom class or function for demonstration, because lots of people won't know the signature of Parameter by heart, and one might not understand that Parameter is imported here for the sake of making an example. Lots of people might be mislead thinking it is used to "do" something (and not just be the object of demonstration). Apr 9 at 9:09
  • @JonathanScholbach -- you're probably right. I edited my post to reflect this. I kept the original code too, since you reference it. The original is more elegant an concise, but less relatable to all, indeed.
    – thorwhalen
    Apr 9 at 12:47
  • We can delete the comment and the appendix, if you want. :) Apr 9 at 12:56
  • @JonathanScholbach: This is still a mypy error: error: Parameter 1 of Literal[...] is invalid [valid-type]. It's merely a slightly different syntax to write essentially the same thing Chris Goddard's answer does, with all the same problems. Apr 10 at 1:53
  • The fact that you can write Literal[*valid_values] is simply due to a change in Python's indexing syntax, not due to any changes in what's actually considered a valid way to use Literal. The dev team didn't change their mind on whether it should be okay to use Literal this way. It's still considered semantically invalid, even if it executes without throwing an exception. Apr 10 at 1:54
-5

Here is the workaround for this. But don't know if it is a good solution.

VALID_ARGUMENTS = ['foo', 'bar']

Argument = Literal['1']

Argument.__args__ = tuple(VALID_ARGUMENTS)

print(Argument)
# typing.Literal['foo', 'bar']
3
  • 5
    Since this performs a runtime modification of the previously defined static type, it will plain not work. The runtime type will be Literal['foo', 'bar'], but the static type actually used for verification is still Literal['1']. Dec 30, 2020 at 19:32
  • @MisterMiyagi I use this solution with FastAPI + Pydantic. It works good for a field validation. I can only pass foo or bar values to my API with a POST request, but not a 1 value.
    – user9608133
    Feb 28, 2021 at 9:02
  • @AlexeiMarinichenko That’s nice, but does not change that it will plain not work for its intended use. The question already shows two cases that also work at runtime but are considerably more robust than fiddling with implementation specific internals. Feb 28, 2021 at 9:40

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