Annotations Best Practices — Python documentation
Annotations Best Practices
- author
- Larry Hastings
Abstract
This document is designed to encapsulate the best practices for working with annotations dicts. If you write Python code that examines __annotations__
on Python objects, we encourage you to follow the guidelines described below.
The document is organized into four sections: best practices for accessing the annotations of an object in Python versions 3.10 and newer, best practices for accessing the annotations of an object in Python versions 3.9 and older, other best practices for __annotations__
that apply to any Python version, and quirks of __annotations__
.
Note that this document is specifically about working with __annotations__
, not uses for annotations. If you’re looking for information on how to use “type hints” in your code, please see the typing module.
Accessing The Annotations Dict Of An Object In Python 3.10 And Newer
Python 3.10 adds a new function to the standard library: inspect.get_annotations(). In Python versions 3.10 and newer, calling this function is the best practice for accessing the annotations dict of any object that supports annotations. This function can also “un-stringize” stringized annotations for you.
If for some reason inspect.get_annotations() isn’t viable for your use case, you may access the
__annotations__
data member manually. Best practice for this changed in Python 3.10 as well: as of Python 3.10,o.__annotations__
is guaranteed to always work on Python functions, classes, and modules. If you’re certain the object you’re examining is one of these three specific objects, you may simply useo.__annotations__
to get at the object’s annotations dict.However, other types of callables–for example, callables created by functools.partial()–may not have an
__annotations__
attribute defined. When accessing the__annotations__
of a possibly unknown object, best practice in Python versions 3.10 and newer is to call getattr() with three arguments, for examplegetattr(o, '__annotations__', None)
.
Accessing The Annotations Dict Of An Object In Python 3.9 And Older
In Python 3.9 and older, accessing the annotations dict of an object is much more complicated than in newer versions. The problem is a design flaw in these older versions of Python, specifically to do with class annotations.
Best practice for accessing the annotations dict of other objects–functions, other callables, and modules–is the same as best practice for 3.10, assuming you aren’t calling inspect.get_annotations(): you should use three-argument getattr() to access the object’s
__annotations__
attribute.Unfortunately, this isn’t best practice for classes. The problem is that, since
__annotations__
is optional on classes, and because classes can inherit attributes from their base classes, accessing the__annotations__
attribute of a class may inadvertently return the annotations dict of a base class. As an example:class Base: a: int = 3 b: str = 'abc' class Derived(Base): pass print(Derived.__annotations__)
This will print the annotations dict from
Base
, notDerived
.Your code will have to have a separate code path if the object you’re examining is a class (
isinstance(o, type)
). In that case, best practice relies on an implementation detail of Python 3.9 and before: if a class has annotations defined, they are stored in the class’s__dict__
dictionary. Since the class may or may not have annotations defined, best practice is to call theget
method on the class dict.To put it all together, here is some sample code that safely accesses the
__annotations__
attribute on an arbitrary object in Python 3.9 and before:if isinstance(o, type): ann = o.__dict__.get('__annotations__', None) else: ann = getattr(o, '__annotations__', None)
After running this code,
ann
should be either a dictionary orNone
. You’re encouraged to double-check the type ofann
using isinstance() before further examination.Note that some exotic or malformed type objects may not have a
__dict__
attribute, so for extra safety you may also wish to use getattr() to access__dict__
.
Manually Un-Stringizing Stringized Annotations
In situations where some annotations may be “stringized”, and you wish to evaluate those strings to produce the Python values they represent, it really is best to call inspect.get_annotations() to do this work for you.
If you’re using Python 3.9 or older, or if for some reason you can’t use inspect.get_annotations(), you’ll need to duplicate its logic. You’re encouraged to examine the implementation of inspect.get_annotations() in the current Python version and follow a similar approach.
In a nutshell, if you wish to evaluate a stringized annotation on an arbitrary object
o
:
- If
o
is a module, useo.__dict__
as theglobals
when calling eval().- If
o
is a class, usesys.modules[o.__module__].__dict__
as theglobals
, anddict(vars(o))
as thelocals
, when calling eval().- If
o
is a wrapped callable using functools.update_wrapper(), functools.wraps(), or functools.partial(), iteratively unwrap it by accessing eithero.__wrapped__
oro.func
as appropriate, until you have found the root unwrapped function.- If
o
is a callable (but not a class), useo.__globals__
as the globals when calling eval().However, not all string values used as annotations can be successfully turned into Python values by eval(). String values could theoretically contain any valid string, and in practice there are valid use cases for type hints that require annotating with string values that specifically can’t be evaluated. For example:
- PEP 604 union types using |, before support for this was added to Python 3.10.
- Definitions that aren’t needed at runtime, only imported when typing.TYPE_CHECKING is true.
If eval() attempts to evaluate such values, it will fail and raise an exception. So, when designing a library API that works with annotations, it’s recommended to only attempt to evaluate string values when explicitly requested to by the caller.
Best Practices For __annotations__ In Any Python Version
- You should avoid assigning to the
__annotations__
member of objects directly. Let Python manage setting__annotations__
.- If you do assign directly to the
__annotations__
member of an object, you should always set it to adict
object.- If you directly access the
__annotations__
member of an object, you should ensure that it’s a dictionary before attempting to examine its contents.- You should avoid modifying
__annotations__
dicts.- You should avoid deleting the
__annotations__
attribute of an object.
__annotations__ Quirks
In all versions of Python 3, function objects lazy-create an annotations dict if no annotations are defined on that object. You can delete the
__annotations__
attribute usingdel fn.__annotations__
, but if you then accessfn.__annotations__
the object will create a new empty dict that it will store and return as its annotations. Deleting the annotations on a function before it has lazily created its annotations dict will throw anAttributeError
; usingdel fn.__annotations__
twice in a row is guaranteed to always throw anAttributeError
.Everything in the above paragraph also applies to class and module objects in Python 3.10 and newer.
In all versions of Python 3, you can set
__annotations__
on a function object toNone
. However, subsequently accessing the annotations on that object usingfn.__annotations__
will lazy-create an empty dictionary as per the first paragraph of this section. This is not true of modules and classes, in any Python version; those objects permit setting__annotations__
to any Python value, and will retain whatever value is set.If Python stringizes your annotations for you (using
from __future__ import annotations
), and you specify a string as an annotation, the string will itself be quoted. In effect the annotation is quoted twice. For example:from __future__ import annotations def foo(a: "str"): pass print(foo.__annotations__)
This prints
{'a': "'str'"}
. This shouldn’t really be considered a “quirk”; it’s mentioned here simply because it might be surprising.