Literal types and Enums¶
Literal types¶
Literal types let you indicate that an expression is equal to some specific
primitive value. For example, if we annotate a variable with type Literal["foo"]
,
mypy will understand that variable is not only of type str
, but is also
equal to specifically the string "foo"
.
This feature is primarily useful when annotating functions that behave
differently based on the exact value the caller provides. For example,
suppose we have a function fetch_data(...)
that returns bytes
if the
first argument is True
, and str
if it’s False
. We can construct a
precise type signature for this function using Literal[...]
and overloads:
from typing import overload, Union, Literal
# The first two overloads use Literal[...] so we can
# have precise return types:
@overload
def fetch_data(raw: Literal[True]) -> bytes: ...
@overload
def fetch_data(raw: Literal[False]) -> str: ...
# The last overload is a fallback in case the caller
# provides a regular bool:
@overload
def fetch_data(raw: bool) -> Union[bytes, str]: ...
def fetch_data(raw: bool) -> Union[bytes, str]:
# Implementation is omitted
...
reveal_type(fetch_data(True)) # Revealed type is "bytes"
reveal_type(fetch_data(False)) # Revealed type is "str"
# Variables declared without annotations will continue to have an
# inferred type of 'bool'.
variable = True
reveal_type(fetch_data(variable)) # Revealed type is "Union[bytes, str]"
Note
The examples in this page import Literal
as well as Final
and
TypedDict
from the typing
module. These types were added to
typing
in Python 3.8, but are also available for use in Python
3.4 - 3.7 via the typing_extensions
package.
Parameterizing Literals¶
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.
Literals containing two or more values are equivalent to the union of those values.
So, Literal[-3, b"foo", MyEnum.A]
is equivalent to
Union[Literal[-3], Literal[b"foo"], Literal[MyEnum.A]]
. This makes writing more
complex types involving literals a little more convenient.
Literal types may also contain None
. Mypy will treat Literal[None]
as being
equivalent to just None
. This means that Literal[4, None]
,
Literal[4] | None
, and Optional[Literal[4]]
are all equivalent.
Literals may also contain aliases to other literal types. For example, the following program is legal:
PrimaryColors = Literal["red", "blue", "yellow"]
SecondaryColors = Literal["purple", "green", "orange"]
AllowedColors = Literal[PrimaryColors, SecondaryColors]
def paint(color: AllowedColors) -> None: ...
paint("red") # Type checks!
paint("turquoise") # Does not type check
Literals may not contain any other kind of type or expression. This means doing
Literal[my_instance]
, Literal[Any]
, Literal[3.14]
, or
Literal[{"foo": 2, "bar": 5}]
are all illegal.
Declaring literal variables¶
You must explicitly add an annotation to a variable to declare that it has a literal type:
a: Literal[19] = 19
reveal_type(a) # Revealed type is "Literal[19]"
In order to preserve backwards-compatibility, variables without this annotation are not assumed to be literals:
b = 19
reveal_type(b) # Revealed type is "int"
If you find repeating the value of the variable in the type hint to be tedious,
you can instead change the variable to be Final
(see Final names, methods and classes):
from typing import Final, Literal
def expects_literal(x: Literal[19]) -> None: pass
c: Final = 19
reveal_type(c) # Revealed type is "Literal[19]?"
expects_literal(c) # ...and this type checks!
If you do not provide an explicit type in the Final
, the type of c
becomes
context-sensitive: mypy will basically try “substituting” the original assigned
value whenever it’s used before performing type checking. This is why the revealed
type of c
is Literal[19]?
: the question mark at the end reflects this
context-sensitive nature.
For example, mypy will type check the above program almost as if it were written like so:
from typing import Final, Literal
def expects_literal(x: Literal[19]) -> None: pass
reveal_type(19)
expects_literal(19)
This means that while changing a variable to be Final
is not quite the same thing
as adding an explicit Literal[...]
annotation, it often leads to the same effect
in practice.
The main cases where the behavior of context-sensitive vs true literal types differ are
when you try using those types in places that are not explicitly expecting a Literal[...]
.
For example, compare and contrast what happens when you try appending these types to a list:
from typing import Final, Literal
a: Final = 19
b: Literal[19] = 19
# Mypy will choose to infer list[int] here.
list_of_ints = []
list_of_ints.append(a)
reveal_type(list_of_ints) # Revealed type is "list[int]"
# But if the variable you're appending is an explicit Literal, mypy
# will infer list[Literal[19]].
list_of_lits = []
list_of_lits.append(b)
reveal_type(list_of_lits) # Revealed type is "list[Literal[19]]"
Intelligent indexing¶
We can use Literal types to more precisely index into structured heterogeneous types such as tuples, NamedTuples, and TypedDicts. This feature is known as intelligent indexing.
For example, when we index into a tuple using some int, the inferred type is normally the union of the tuple item types. However, if we want just the type corresponding to some particular index, we can use Literal types like so:
from typing import TypedDict
tup = ("foo", 3.4)
# Indexing with an int literal gives us the exact type for that index
reveal_type(tup[0]) # Revealed type is "str"
# But what if we want the index to be a variable? Normally mypy won't
# know exactly what the index is and so will return a less precise type:
int_index = 0
reveal_type(tup[int_index]) # Revealed type is "Union[str, float]"
# But if we use either Literal types or a Final int, we can gain back
# the precision we originally had:
lit_index: Literal[0] = 0
fin_index: Final = 0
reveal_type(tup[lit_index]) # Revealed type is "str"
reveal_type(tup[fin_index]) # Revealed type is "str"
# We can do the same thing with with TypedDict and str keys:
class MyDict(TypedDict):
name: str
main_id: int
backup_id: int
d: MyDict = {"name": "Saanvi", "main_id": 111, "backup_id": 222}
name_key: Final = "name"
reveal_type(d[name_key]) # Revealed type is "str"
# You can also index using unions of literals
id_key: Literal["main_id", "backup_id"]
reveal_type(d[id_key]) # Revealed type is "int"
Tagged unions¶
When you have a union of types, you can normally discriminate between each type
in the union by using isinstance
checks. For example, if you had a variable x
of
type Union[int, str]
, you could write some code that runs only if x
is an int
by doing if isinstance(x, int): ...
.
However, it is not always possible or convenient to do this. For example, it is not
possible to use isinstance
to distinguish between two different TypedDicts since
at runtime, your variable will simply be just a dict.
Instead, what you can do is label or tag your TypedDicts with a distinct Literal type. Then, you can discriminate between each kind of TypedDict by checking the label:
from typing import Literal, TypedDict, Union
class NewJobEvent(TypedDict):
tag: Literal["new-job"]
job_name: str
config_file_path: str
class CancelJobEvent(TypedDict):
tag: Literal["cancel-job"]
job_id: int
Event = Union[NewJobEvent, CancelJobEvent]
def process_event(event: Event) -> None:
# Since we made sure both TypedDicts have a key named 'tag', it's
# safe to do 'event["tag"]'. This expression normally has the type
# Literal["new-job", "cancel-job"], but the check below will narrow
# the type to either Literal["new-job"] or Literal["cancel-job"].
#
# This in turns narrows the type of 'event' to either NewJobEvent
# or CancelJobEvent.
if event["tag"] == "new-job":
print(event["job_name"])
else:
print(event["job_id"])
While this feature is mostly useful when working with TypedDicts, you can also use the same technique with regular objects, tuples, or namedtuples.
Similarly, tags do not need to be specifically str Literals: they can be any type
you can normally narrow within if
statements and the like. For example, you
could have your tags be int or Enum Literals or even regular classes you narrow
using isinstance()
(Python 3.12 syntax):
class Wrapper[T]:
def __init__(self, inner: T) -> None:
self.inner = inner
def process(w: Wrapper[int] | Wrapper[str]) -> None:
# Doing `if isinstance(w, Wrapper[int])` does not work: isinstance requires
# that the second argument always be an *erased* type, with no generics.
# This is because generics are a typing-only concept and do not exist at
# runtime in a way `isinstance` can always check.
#
# However, we can side-step this by checking the type of `w.inner` to
# narrow `w` itself:
if isinstance(w.inner, int):
reveal_type(w) # Revealed type is "Wrapper[int]"
else:
reveal_type(w) # Revealed type is "Wrapper[str]"
This feature is sometimes called “sum types” or “discriminated union types” in other programming languages.
Exhaustiveness checking¶
You may want to check that some code covers all possible
Literal
or Enum
cases. Example:
from typing import Literal
PossibleValues = Literal['one', 'two']
def validate(x: PossibleValues) -> bool:
if x == 'one':
return True
elif x == 'two':
return False
raise ValueError(f'Invalid value: {x}')
assert validate('one') is True
assert validate('two') is False
In the code above, it’s easy to make a mistake. You can
add a new literal value to PossibleValues
but forget
to handle it in the validate
function:
PossibleValues = Literal['one', 'two', 'three']
Mypy won’t catch that 'three'
is not covered. If you want mypy to
perform an exhaustiveness check, you need to update your code to use an
assert_never()
check:
from typing import Literal, NoReturn
from typing_extensions import assert_never
PossibleValues = Literal['one', 'two']
def validate(x: PossibleValues) -> bool:
if x == 'one':
return True
elif x == 'two':
return False
assert_never(x)
Now if you add a new value to PossibleValues
but don’t update validate
,
mypy will spot the error:
PossibleValues = Literal['one', 'two', 'three']
def validate(x: PossibleValues) -> bool:
if x == 'one':
return True
elif x == 'two':
return False
# Error: Argument 1 to "assert_never" has incompatible type "Literal['three']";
# expected "NoReturn"
assert_never(x)
If runtime checking against unexpected values is not needed, you can
leave out the assert_never
call in the above example, and mypy
will still generate an error about function validate
returning
without a value:
PossibleValues = Literal['one', 'two', 'three']
# Error: Missing return statement
def validate(x: PossibleValues) -> bool:
if x == 'one':
return True
elif x == 'two':
return False
Exhaustiveness checking is also supported for match statements (Python 3.10 and later):
def validate(x: PossibleValues) -> bool:
match x:
case 'one':
return True
case 'two':
return False
assert_never(x)
Limitations¶
Mypy will not understand expressions that use variables of type Literal[..]
on a deep level. For example, if you have a variable a
of type Literal[3]
and another variable b
of type Literal[5]
, mypy will infer that
a + b
has type int
, not type Literal[8]
.
The basic rule is that literal types are treated as just regular subtypes of
whatever type the parameter has. For example, Literal[3]
is treated as a
subtype of int
and so will inherit all of int
’s methods directly. This
means that Literal[3].__add__
accepts the same arguments and has the same
return type as int.__add__
.
Enums¶
Mypy has special support for enum.Enum
and its subclasses:
enum.IntEnum
, enum.Flag
, enum.IntFlag
,
and enum.StrEnum
.
from enum import Enum
class Direction(Enum):
up = 'up'
down = 'down'
reveal_type(Direction.up) # Revealed type is "Literal[Direction.up]?"
reveal_type(Direction.down) # Revealed type is "Literal[Direction.down]?"
You can use enums to annotate types as you would expect:
class Movement:
def __init__(self, direction: Direction, speed: float) -> None:
self.direction = direction
self.speed = speed
Movement(Direction.up, 5.0) # ok
Movement('up', 5.0) # E: Argument 1 to "Movement" has incompatible type "str"; expected "Direction"
Exhaustiveness checking¶
Similar to Literal
types, Enum
supports exhaustiveness checking.
Let’s start with a definition:
from enum import Enum
from typing import NoReturn
from typing_extensions import assert_never
class Direction(Enum):
up = 'up'
down = 'down'
Now, let’s use an exhaustiveness check:
def choose_direction(direction: Direction) -> None:
if direction is Direction.up:
reveal_type(direction) # N: Revealed type is "Literal[Direction.up]"
print('Going up!')
return
elif direction is Direction.down:
print('Down')
return
# This line is never reached
assert_never(direction)
If we forget to handle one of the cases, mypy will generate an error:
def choose_direction(direction: Direction) -> None:
if direction == Direction.up:
print('Going up!')
return
assert_never(direction) # E: Argument 1 to "assert_never" has incompatible type "Direction"; expected "NoReturn"
Exhaustiveness checking is also supported for match statements (Python 3.10 and later).
Extra Enum checks¶
Mypy also tries to support special features of Enum
the same way Python’s runtime does:
Any
Enum
class with values is implicitly final. This is what happens in CPython:>>> class AllDirection(Direction): ... left = 'left' ... right = 'right' Traceback (most recent call last): ... TypeError: AllDirection: cannot extend enumeration 'Direction'
Mypy also catches this error:
class AllDirection(Direction): # E: Cannot inherit from final class "Direction" left = 'left' right = 'right'
All
Enum
fields are implicitlyfinal
as well.Direction.up = '^' # E: Cannot assign to final attribute "up"
All field names are checked to be unique.
class Some(Enum): x = 1 x = 2 # E: Attempted to reuse member name "x" in Enum definition "Some"
Base classes have no conflicts and mixin types are correct.
class WrongEnum(str, int, enum.Enum): # E: Only a single data type mixin is allowed for Enum subtypes, found extra "int" ... class MixinAfterEnum(enum.Enum, Mixin): # E: No base classes are allowed after "enum.Enum" ...