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Make a top-level TypedDict page (#14584)
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This just moves content around (with minimal editing to make the moves
make sense).

TypedDict has been the target for several features, including some that
are not yet documented. There was another PEP drafted today that was
TypedDict themed. It's also pretty popular with users.

Linking #13681
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hauntsaninja committed Feb 3, 2023
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1 change: 1 addition & 0 deletions docs/source/index.rst
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generics
more_types
literal_types
typed_dict
final_attrs
metaclasses

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254 changes: 1 addition & 253 deletions docs/source/more_types.rst
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Expand Up @@ -2,7 +2,7 @@ More types
==========

This section introduces a few additional kinds of types, including :py:data:`~typing.NoReturn`,
:py:func:`NewType <typing.NewType>`, ``TypedDict``, and types for async code. It also discusses
:py:func:`NewType <typing.NewType>`, and types for async code. It also discusses
how to give functions more precise types using overloads. All of these are only
situationally useful, so feel free to skip this section and come back when you
have a need for some of them.
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signatures. This is useful if you need to encode a relationship between the
arguments and the return type that would be difficult to express normally.

* ``TypedDict`` lets you give precise types for dictionaries that represent
objects with a fixed schema, such as ``{'id': 1, 'items': ['x']}``.

* Async types let you type check programs using ``async`` and ``await``.

.. _noreturn:
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loop = asyncio.get_event_loop()
loop.run_until_complete(countdown_2("USS Enterprise", 5))
loop.close()
.. _typeddict:

TypedDict
*********

Python programs often use dictionaries with string keys to represent objects.
Here is a typical example:

.. code-block:: python
movie = {'name': 'Blade Runner', 'year': 1982}
Only a fixed set of string keys is expected (``'name'`` and
``'year'`` above), and each key has an independent value type (``str``
for ``'name'`` and ``int`` for ``'year'`` above). We've previously
seen the ``dict[K, V]`` type, which lets you declare uniform
dictionary types, where every value has the same type, and arbitrary keys
are supported. This is clearly not a good fit for
``movie`` above. Instead, you can use a ``TypedDict`` to give a precise
type for objects like ``movie``, where the type of each
dictionary value depends on the key:

.. code-block:: python
from typing_extensions import TypedDict
Movie = TypedDict('Movie', {'name': str, 'year': int})
movie: Movie = {'name': 'Blade Runner', 'year': 1982}
``Movie`` is a ``TypedDict`` type with two items: ``'name'`` (with type ``str``)
and ``'year'`` (with type ``int``). Note that we used an explicit type
annotation for the ``movie`` variable. This type annotation is
important -- without it, mypy will try to infer a regular, uniform
:py:class:`dict` type for ``movie``, which is not what we want here.

.. note::

If you pass a ``TypedDict`` object as an argument to a function, no
type annotation is usually necessary since mypy can infer the
desired type based on the declared argument type. Also, if an
assignment target has been previously defined, and it has a
``TypedDict`` type, mypy will treat the assigned value as a ``TypedDict``,
not :py:class:`dict`.

Now mypy will recognize these as valid:

.. code-block:: python
name = movie['name'] # Okay; type of name is str
year = movie['year'] # Okay; type of year is int
Mypy will detect an invalid key as an error:

.. code-block:: python
director = movie['director'] # Error: 'director' is not a valid key
Mypy will also reject a runtime-computed expression as a key, as
it can't verify that it's a valid key. You can only use string
literals as ``TypedDict`` keys.

The ``TypedDict`` type object can also act as a constructor. It
returns a normal :py:class:`dict` object at runtime -- a ``TypedDict`` does
not define a new runtime type:

.. code-block:: python
toy_story = Movie(name='Toy Story', year=1995)
This is equivalent to just constructing a dictionary directly using
``{ ... }`` or ``dict(key=value, ...)``. The constructor form is
sometimes convenient, since it can be used without a type annotation,
and it also makes the type of the object explicit.

Like all types, ``TypedDict``\s can be used as components to build
arbitrarily complex types. For example, you can define nested
``TypedDict``\s and containers with ``TypedDict`` items.
Unlike most other types, mypy uses structural compatibility checking
(or structural subtyping) with ``TypedDict``\s. A ``TypedDict`` object with
extra items is compatible with (a subtype of) a narrower
``TypedDict``, assuming item types are compatible (*totality* also affects
subtyping, as discussed below).

A ``TypedDict`` object is not a subtype of the regular ``dict[...]``
type (and vice versa), since :py:class:`dict` allows arbitrary keys to be
added and removed, unlike ``TypedDict``. However, any ``TypedDict`` object is
a subtype of (that is, compatible with) ``Mapping[str, object]``, since
:py:class:`~typing.Mapping` only provides read-only access to the dictionary items:

.. code-block:: python
def print_typed_dict(obj: Mapping[str, object]) -> None:
for key, value in obj.items():
print(f'{key}: {value}')
print_typed_dict(Movie(name='Toy Story', year=1995)) # OK
.. note::

Unless you are on Python 3.8 or newer (where ``TypedDict`` is available in
standard library :py:mod:`typing` module) you need to install ``typing_extensions``
using pip to use ``TypedDict``:

.. code-block:: text
python3 -m pip install --upgrade typing-extensions
Totality
--------

By default mypy ensures that a ``TypedDict`` object has all the specified
keys. This will be flagged as an error:

.. code-block:: python
# Error: 'year' missing
toy_story: Movie = {'name': 'Toy Story'}
Sometimes you want to allow keys to be left out when creating a
``TypedDict`` object. You can provide the ``total=False`` argument to
``TypedDict(...)`` to achieve this:

.. code-block:: python
GuiOptions = TypedDict(
'GuiOptions', {'language': str, 'color': str}, total=False)
options: GuiOptions = {} # Okay
options['language'] = 'en'
You may need to use :py:meth:`~dict.get` to access items of a partial (non-total)
``TypedDict``, since indexing using ``[]`` could fail at runtime.
However, mypy still lets use ``[]`` with a partial ``TypedDict`` -- you
just need to be careful with it, as it could result in a :py:exc:`KeyError`.
Requiring :py:meth:`~dict.get` everywhere would be too cumbersome. (Note that you
are free to use :py:meth:`~dict.get` with total ``TypedDict``\s as well.)

Keys that aren't required are shown with a ``?`` in error messages:

.. code-block:: python
# Revealed type is "TypedDict('GuiOptions', {'language'?: builtins.str,
# 'color'?: builtins.str})"
reveal_type(options)
Totality also affects structural compatibility. You can't use a partial
``TypedDict`` when a total one is expected. Also, a total ``TypedDict`` is not
valid when a partial one is expected.

Supported operations
--------------------

``TypedDict`` objects support a subset of dictionary operations and methods.
You must use string literals as keys when calling most of the methods,
as otherwise mypy won't be able to check that the key is valid. List
of supported operations:

* Anything included in :py:class:`~typing.Mapping`:

* ``d[key]``
* ``key in d``
* ``len(d)``
* ``for key in d`` (iteration)
* :py:meth:`d.get(key[, default]) <dict.get>`
* :py:meth:`d.keys() <dict.keys>`
* :py:meth:`d.values() <dict.values>`
* :py:meth:`d.items() <dict.items>`

* :py:meth:`d.copy() <dict.copy>`
* :py:meth:`d.setdefault(key, default) <dict.setdefault>`
* :py:meth:`d1.update(d2) <dict.update>`
* :py:meth:`d.pop(key[, default]) <dict.pop>` (partial ``TypedDict``\s only)
* ``del d[key]`` (partial ``TypedDict``\s only)

.. note::

:py:meth:`~dict.clear` and :py:meth:`~dict.popitem` are not supported since they are unsafe
-- they could delete required ``TypedDict`` items that are not visible to
mypy because of structural subtyping.

Class-based syntax
------------------

An alternative, class-based syntax to define a ``TypedDict`` is supported
in Python 3.6 and later:

.. code-block:: python
from typing_extensions import TypedDict
class Movie(TypedDict):
name: str
year: int
The above definition is equivalent to the original ``Movie``
definition. It doesn't actually define a real class. This syntax also
supports a form of inheritance -- subclasses can define additional
items. However, this is primarily a notational shortcut. Since mypy
uses structural compatibility with ``TypedDict``\s, inheritance is not
required for compatibility. Here is an example of inheritance:

.. code-block:: python
class Movie(TypedDict):
name: str
year: int
class BookBasedMovie(Movie):
based_on: str
Now ``BookBasedMovie`` has keys ``name``, ``year`` and ``based_on``.

Mixing required and non-required items
--------------------------------------

In addition to allowing reuse across ``TypedDict`` types, inheritance also allows
you to mix required and non-required (using ``total=False``) items
in a single ``TypedDict``. Example:

.. code-block:: python
class MovieBase(TypedDict):
name: str
year: int
class Movie(MovieBase, total=False):
based_on: str
Now ``Movie`` has required keys ``name`` and ``year``, while ``based_on``
can be left out when constructing an object. A ``TypedDict`` with a mix of required
and non-required keys, such as ``Movie`` above, will only be compatible with
another ``TypedDict`` if all required keys in the other ``TypedDict`` are required keys in the
first ``TypedDict``, and all non-required keys of the other ``TypedDict`` are also non-required keys
in the first ``TypedDict``.

Unions of TypedDicts
--------------------

Since TypedDicts are really just regular dicts at runtime, it is not possible to
use ``isinstance`` checks to distinguish between different variants of a Union of
TypedDict in the same way you can with regular objects.

Instead, you can use the :ref:`tagged union pattern <tagged_unions>`. The referenced
section of the docs has a full description with an example, but in short, you will
need to give each TypedDict the same key where each value has a unique
:ref:`Literal type <literal_types>`. Then, check that key to distinguish
between your TypedDicts.
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