687

I have the following code in python 3:

class Position:

    def __init__(self, x: int, y: int):
        self.x = x
        self.y = y

    def __add__(self, other: Position) -> Position:
        return Position(self.x + other.x, self.y + other.y)

But my editor (PyCharm) says that the reference Position can not be resolved (in the __add__ method). How should I specify that I expect the return type to be of type Position?

Edit: I think this is actually a PyCharm issue. It actually uses the information in its warnings, and code completion

But correct me if I'm wrong, and need to use some other syntax.

0
982

TL;DR: If you are using Python 3.10 or later, it just works. As of today (2019), in 3.7+ you must turn this feature on using a future statement (from __future__ import annotations). In Python 3.6 or below, use a string.

I guess you got this exception:

NameError: name 'Position' is not defined

This is because Position must be defined before you can use it in an annotation unless you are using Python 3.10 or later.

Python 3.7+: from __future__ import annotations

Python 3.7 introduces PEP 563: postponed evaluation of annotations. A module that uses the future statement from __future__ import annotations will store annotations as strings automatically:

from __future__ import annotations

class Position:
    def __add__(self, other: Position) -> Position:
        ...

This is scheduled to become the default in Python 3.10. Since Python still is a dynamically typed language so no type checking is done at runtime, typing annotations should have no performance impact, right? Wrong! Before python 3.7 the typing module used to be one of the slowest python modules in core so if you import typing you will see up to 7 times increase in performance when you upgrade to 3.7.

Python <3.7: use a string

According to PEP 484, you should use a string instead of the class itself:

class Position:
    ...
    def __add__(self, other: 'Position') -> 'Position':
       ...

If you use the Django framework this may be familiar as Django models also use strings for forward references (foreign key definitions where the foreign model is self or is not declared yet). This should work with Pycharm and other tools.

Sources

The relevant parts of PEP 484 and PEP 563, to spare you the trip:

Forward references

When a type hint contains names that have not been defined yet, that definition may be expressed as a string literal, to be resolved later.

A situation where this occurs commonly is the definition of a container class, where the class being defined occurs in the signature of some of the methods. For example, the following code (the start of a simple binary tree implementation) does not work:

class Tree:
    def __init__(self, left: Tree, right: Tree):
        self.left = left
        self.right = right

To address this, we write:

class Tree:
    def __init__(self, left: 'Tree', right: 'Tree'):
        self.left = left
        self.right = right

The string literal should contain a valid Python expression (i.e., compile(lit, '', 'eval') should be a valid code object) and it should evaluate without errors once the module has been fully loaded. The local and global namespace in which it is evaluated should be the same namespaces in which default arguments to the same function would be evaluated.

and PEP 563:

Implementation

In Python 3.10, function and variable annotations will no longer be evaluated at definition time. Instead, a string form will be preserved in the respective __annotations__ dictionary. Static type checkers will see no difference in behavior, whereas tools using annotations at runtime will have to perform postponed evaluation.

...

Enabling the future behavior in Python 3.7

The functionality described above can be enabled starting from Python 3.7 using the following special import:

from __future__ import annotations

Things that you may be tempted to do instead

A. Define a dummy Position

Before the class definition, place a dummy definition:

class Position(object):
    pass


class Position(object):
    ...

This will get rid of the NameError and may even look OK:

>>> Position.__add__.__annotations__
{'other': __main__.Position, 'return': __main__.Position}

But is it?

>>> for k, v in Position.__add__.__annotations__.items():
...     print(k, 'is Position:', v is Position)                                                                                                                                                                                                                  
return is Position: False
other is Position: False

B. Monkey-patch in order to add the annotations:

You may want to try some Python meta programming magic and write a decorator to monkey-patch the class definition in order to add annotations:

class Position:
    ...
    def __add__(self, other):
        return self.__class__(self.x + other.x, self.y + other.y)

The decorator should be responsible for the equivalent of this:

Position.__add__.__annotations__['return'] = Position
Position.__add__.__annotations__['other'] = Position

At least it seems right:

>>> for k, v in Position.__add__.__annotations__.items():
...     print(k, 'is Position:', v is Position)                                                                                                                                                                                                                  
return is Position: True
other is Position: True

Probably too much trouble.

12
  • 4
    Right, this is less a PyCharm issue and more a Python 3.5 PEP 484 issue. I suspect you'd get the same warning if you ran it through the mypy type tool. – Paul Everitt Nov 5 '15 at 13:36
  • 57
    > if you are using Python 4.0 it just works by the way, have you seen Sarah Connor? :) – scrutari Jul 24 '19 at 13:51
  • @JoelBerkeley I just tested it and type parameters worked for me on 3.6, just don't forget to import from typing as any type you use must be in scope when the string is evaluated. – Paulo Scardine Aug 20 '19 at 16:07
  • ah, my mistake, i was only putting '' round the class, not the type parameters – joel Aug 20 '19 at 16:57
  • 14
    Important note to anyone using from __future__ import annotations - this must be imported before all other imports. – Artur Nov 7 '19 at 12:06
21

Specifying the type as string is fine, but always grates me a bit that we are basically circumventing the parser. So you better not misspell any one of these literal strings:

def __add__(self, other: 'Position') -> 'Position':
    return Position(self.x + other.x, self.y + other.y)

A slight variation is to use a bound typevar, at least then you have to write the string only once when declaring the typevar:

from typing import TypeVar

T = TypeVar('T', bound='Position')

class Position:

    def __init__(self, x: int, y: int):
        self.x = x
        self.y = y

    def __add__(self, other: T) -> T:
        return Position(self.x + other.x, self.y + other.y)
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  • 22
    I wish Python had a typing.Self to specify this explicitly. – Alexander Huszagh Mar 15 '19 at 16:08
  • 2
    I came here looking to see if something like your typing.Self existed. Returning a hard coded string fails to return the correct type when leveraging polymorphism. In my case I wanted to implement a deserialize classmethod. I settled on returning a dict (kwargs) and calling some_class(**some_class.deserialize(raw_data)). – Scott P. Mar 17 '19 at 16:56
  • 1
    The type annotations used here are appropriate when implementing this correctly to use subclasses. However, the implementation returns Position, and not the class, so the example above is technically incorrect. The implementation should replace Position( with something like self.__class__(. – Sam Bull Jun 7 '20 at 15:01
  • 1
    Additionally, the annotations say that the return type depends on other, but most probably it actually depends on self. So, you would need to put the annotation on self to describe the correct behaviour (and maybe other should just be Position to show that it's not tied to the return type). This can also be used for cases when you are only working with self. e.g. def __aenter__(self: T) -> T: – Sam Bull Jun 7 '20 at 15:05
  • The current implementation does not return a T (subclass of Position), but a Position (base class). So the type hint -> T is incorrect. You can of course return type(self)(self.x + other.x, self.y + other.y) – MacFreek Aug 3 '20 at 21:13
16

The name 'Position' is not avalilable at the time the class body itself is parsed. I don't know how you are using the type declarations, but Python's PEP 484 - which is what most mode should use if using these typing hints say that you can simply put the name as a string at this point:

def __add__(self, other: 'Position') -> 'Position':
    return Position(self.x + other.x, self.y + other.y)

Check https://www.python.org/dev/peps/pep-0484/#forward-references - tools conforming to that will know to unwrap the class name from there and make use of it.(It is always important to have in mind that the Python language itself does nothing of these annotations - they are usually meant for static-code analysis, or one could have a library/framework for type checking in run-time - but you have to explicitly set that).

update Also, as of Python 3.7, check pep-563 - as of Python 3.8 it is possible to write from __future__ import annotations to defer the evaluation of annotations - forward referencing classes should work straightforward.

0
15

When a string-based type hint is acceptable, the __qualname__ item can also be used. It holds the name of the class, and it is available in the body of the class definition.

class MyClass:
    @classmethod
    def make_new(cls) -> __qualname__:
        return cls()

By doing this, renaming the class does not imply modifying the type hints. But I personally would not expect smart code editors to handle this form well.

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  • 5
    This is especially useful because it does not hardcode the class name, so it keeps working in subclasses. – Florian Brucker Dec 17 '19 at 13:08
  • I'm not sure whether this will work with the postponed evaluation of annotations (PEP 563), so I've asked a question for that. – Florian Brucker Dec 17 '19 at 13:45
  • Note that this is not a valid annotation as far as mypy is concerned. – MisterMiyagi Jul 7 '20 at 9:00
  • this solution fixes the hardcoding in a different manner – user2426679 Nov 21 '20 at 1:51
8

If you only care about fixing the NameError: name 'Position' is not defined, you can either specify the class name as a string:

def __add__(self, other: 'Position') -> 'Position':

Or if you use Python 3.7 or higher, add the following line to the top of your code (just before the other imports)

from __future__ import annotations

However, if you also want this to work for subclasses, and return the specific subclass, you need to use a Generic class, by define a TypeVar.

What is slightly uncommon is that the TypeVar is bound to the type of self. Basically, this typing hinting tells the type checker that the return type of __add__() and copy() are the same type as self.

from __future__ import annotations

from typing import TypeVar

T = TypeVar('T', bound=Position)

class Position:
    
    def __init__(self, x: int, y: int):
        self.x = x
        self.y = y
    
    def __add__(self: T, other: Position) -> T:
        return type(self)(self.x + other.x, self.y + other.y)
    
    def copy(self: T) -> T:
        return type(self)(self.x, self.y)
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  • 1
    @Arjan. you are right. I'm so accustomed to from __future__ import annotations that I probably forgot. Thanks for pointing this out. I fixed it in the answer. – MacFreek Sep 26 '20 at 18:39
  • what is the letter ' T ' ? – Heetola Nov 19 '20 at 9:34
  • @Eildosa: "T" is defined as a TypeVar. Think of it as "any type". In the defintion copy(self: T) -> T this means that whatever object you throw at copy(), copy() will always return an object of the same type. In this case, T is a TypeVar "bound" to Postion, which means "any type that is either Position, or a subclass of Position". Search for TypeVar to learn more about it. – MacFreek Nov 20 '20 at 19:53
  • Are there any clever tricks to have a generic Self that can be reused? – ofo Apr 11 at 4:41
5

I ❤️ Paulo's answer

However, there's a point to be made about type hint inheritance in relation to self, which is that if you type hint by using a literal copy paste of the class name as a string, then your type hint won't inherit in a correct or consistent way.

The solution to this is to provide return type hint by putting the type hint on the return in the function itself.

✅ For example, do this:

class DynamicParent:
  def func(self):
    # roundabout way of returning self in order to have inherited type hints of the return
    # https://stackoverflow.com/a/64938978
    _self:self.__class__ = self
    return _self

Instead of doing this:

class StaticParent:
  def func(self) -> 'StaticParent':
    return self

Below is the reason why you want to do the type hint via the roundabout ✅ way shown above

class StaticChild(StaticParent):
  pass

class DynamicChild(DynamicParent):
  pass

static_child = StaticChild()
dynamic_child = DynamicChild()

dynamic_child screenshot shows that type hinting works correctly when referencing the self:

enter image description here

static_child screenshot shows that type hinting is mistakenly pointing at the parent class, i.e. the type hint does not change correctly with inheritance; it is static because it will always point at the parent even when it should point at the child

enter image description here

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