docs/source/quality.rst - platform/external/python/typing - Git at Google

 .. _tools:

 ********************************************
 Testing and Ensuring Type Annotation Quality
 ********************************************

 Testing Annotation Accuracy
 ===========================

 When creating a package with type annotations, authors may want to validate
 that the annotations they publish meet their expectations.
 This is especially important for library authors, for whom the published
 annotations are part of the public interface to their package.

 There are several approaches to this problem, and this document will show
 a few of them.

 .. note::

     For simplicity, we will assume that type-checking is done with ``mypy``.
     Many of these strategies can be applied to other type-checkers as well.

 Testing Using ``mypy --warn-unused-ignores``
 --------------------------------------------

 Clever use of ``--warn-unused-ignores`` can be used to check that certain
 expressions are or are not well-typed.

 The idea is to write normal python files which contain valid expressions along
 with invalid expressions annotated with ``type: ignore`` comments. When
 ``mypy --warn-unused-ignores`` is run on these files, it should pass.
 A directory of test files, ``typing_tests/``, can be maintained.

 This strategy does not offer strong guarantees about the types under test, but
 it requires no additional tooling.

 If the following file is under test

 .. code-block:: python

     # foo.py
     def bar(x: int) -> str:
         return str(x)

 Then the following file tests ``foo.py``:

 .. code-block:: python

     bar(42)
     bar("42")  # type: ignore [arg-type]
     bar(y=42)  # type: ignore [call-arg]
     r1: str = bar(42)
     r2: int = bar(42)  # type: ignore [assignment]

 Checking ``reveal_type`` output from ``mypy.api.run``
 -----------------------------------------------------

 ``mypy`` provides a subpackage named ``api`` for invoking ``mypy`` from a
 python process. In combination with ``reveal_type``, this can be used to write
 a function which gets the ``reveal_type`` output from an expression. Once
 that's obtained, tests can assert strings and regular expression matches
 against it.

 This approach requires writing a set of helpers to provide a good testing
 experience, and it runs mypy once per test case (which can be slow).
 However, it builds only on ``mypy`` and the test framework of your choice.

 The following example could be integrated into a testsuite written in
 any framework:

 .. code-block:: python

     import re
     from mypy import api

     def get_reveal_type_output(filename):
         result = api.run([filename])
         stdout = result[0]
         match = re.search(r'note: Revealed type is "([^"]+)"', stdout)
         assert match is not None
         return match.group(1)


 For example, we can use the above to provide a ``run_reveal_type`` pytest
 fixture which generates a temporary file and uses it as the input to
 ``get_reveal_type_output``:

 .. code-block:: python

     import os
     import pytest

     @pytest.fixture
     def _in_tmp_path(tmp_path):
         cur = os.getcwd()
         try:
             os.chdir(tmp_path)
             yield
         finally:
             os.chdir(cur)

     @pytest.fixture
     def run_reveal_type(tmp_path, _in_tmp_path):
         content_path = tmp_path / "reveal_type_test.py"

         def func(code_snippet, *, preamble = ""):
             content_path.write_text(preamble + f"reveal_type({code_snippet})")
             return get_reveal_type_output("reveal_type_test.py")

         return func


 For more details, see `the documentation on mypy.api
 <https://mypy.readthedocs.io/en/stable/extending_mypy.html#integrating-mypy-into-another-python-application>`_.

 pytest-mypy-plugins
 -------------------

 `pytest-mypy-plugins <https://github.com/typeddjango/pytest-mypy-plugins>`_ is
 a plugin for ``pytest`` which defines typing test cases as YAML data.
 The test cases are run through ``mypy`` and the output of ``reveal_type`` can
 be asserted.

 This project supports complex typing arrangements like ``pytest`` parametrized
 tests and per-test ``mypy`` configuration. It requires that you are using
 ``pytest`` to run your tests, and runs ``mypy`` in a subprocess per test case.

 This is an example of a parametrized test with ``pytest-mypy-plugins``:

 .. code-block:: yaml

     - case: with_params
       parametrized:
         - val: 1
           rt: builtins.int
         - val: 1.0
           rt: builtins.float
       main: |
         reveal_type({[ val }})  # N: Revealed type is '{{ rt }}'

 Improving Type Completeness
 ===========================

 One of the goals of many libraries is to ensure that they are "fully type
 annotated", meaning that they provide complete and accurate type annotations
 for all functions, classes, and objects. Having full annotations is referred to
 as "type completeness" or "type coverage".

 Here are some tips for increasing the type completeness score for your
 library:

 -  Make type completeness an output of your testing process. Several type
    checkers have options for generating useful output, warnings, or even
    reports.
 -  If your package includes tests or sample code, consider removing them
    from the distribution. If there is good reason to include them,
    consider placing them in a directory that begins with an underscore
    so they are not considered part of your library’s interface.
 -  If your package includes submodules that are meant to be
    implementation details, rename those files to begin with an
    underscore.
 -  If a symbol is not intended to be part of the library’s interface and
    is considered an implementation detail, rename it such that it begins
    with an underscore. It will then be considered private and excluded
    from the type completeness check.
 -  If your package exposes types from other libraries, work with the
    maintainers of these other libraries to achieve type completeness.

 .. warning::

     The ways in which different type checkers evaluate and help you achieve
     better type coverage may differ. Some of the above recommendations may or
     may not be helpful to you, depending on which type checking tools you use.

 ``mypy`` disallow options
 -------------------------

 ``mypy`` offers several options which can detect untyped code.
 More details can be found in `the mypy documentation on these options
 <https://mypy.readthedocs.io/en/latest/command_line.html#untyped-definitions-and-calls>`_.

 Some basic usages which make ``mypy`` error on untyped data are::

     mypy --disallow-untyped-defs
     mypy --disallow-incomplete-defs

 ``pyright`` type verification
 -----------------------------

 pyright has a special command line flag, ``--verifytypes``, for verifying
 type completeness. You can learn more about it from
 `the pyright documentation on verifying type completeness
 <https://github.com/microsoft/pyright/blob/main/docs/typed-libraries.md#verifying-type-completeness>`_.

 ``mypy`` reports
 ----------------

 ``mypy`` offers several options options for generating reports on its analysis.
 See `the mypy documentation on report generation
 <https://mypy.readthedocs.io/en/stable/command_line.html#report-generation>`_ for details.
	.. _tools:

	********************************************
	Testing and Ensuring Type Annotation Quality
	********************************************

	Testing Annotation Accuracy
	===========================

	When creating a package with type annotations, authors may want to validate
	that the annotations they publish meet their expectations.
	This is especially important for library authors, for whom the published
	annotations are part of the public interface to their package.

	There are several approaches to this problem, and this document will show
	a few of them.

	.. note::

	For simplicity, we will assume that type-checking is done with ``mypy``.
	Many of these strategies can be applied to other type-checkers as well.

	Testing Using ``mypy --warn-unused-ignores``
	--------------------------------------------

	Clever use of ``--warn-unused-ignores`` can be used to check that certain
	expressions are or are not well-typed.

	The idea is to write normal python files which contain valid expressions along
	with invalid expressions annotated with ``type: ignore`` comments. When
	``mypy --warn-unused-ignores`` is run on these files, it should pass.
	A directory of test files, ``typing_tests/``, can be maintained.

	This strategy does not offer strong guarantees about the types under test, but
	it requires no additional tooling.

	If the following file is under test

	.. code-block:: python

	# foo.py
	def bar(x: int) -> str:
	return str(x)

	Then the following file tests ``foo.py``:

	.. code-block:: python

	bar(42)
	bar("42") # type: ignore [arg-type]
	bar(y=42) # type: ignore [call-arg]
	r1: str = bar(42)
	r2: int = bar(42) # type: ignore [assignment]

	Checking ``reveal_type`` output from ``mypy.api.run``
	-----------------------------------------------------

	``mypy`` provides a subpackage named ``api`` for invoking ``mypy`` from a
	python process. In combination with ``reveal_type``, this can be used to write
	a function which gets the ``reveal_type`` output from an expression. Once
	that's obtained, tests can assert strings and regular expression matches
	against it.

	This approach requires writing a set of helpers to provide a good testing
	experience, and it runs mypy once per test case (which can be slow).
	However, it builds only on ``mypy`` and the test framework of your choice.

	The following example could be integrated into a testsuite written in
	any framework:

	.. code-block:: python

	import re
	from mypy import api

	def get_reveal_type_output(filename):
	result = api.run([filename])
	stdout = result[0]
	match = re.search(r'note: Revealed type is "([^"]+)"', stdout)
	assert match is not None
	return match.group(1)


	For example, we can use the above to provide a ``run_reveal_type`` pytest
	fixture which generates a temporary file and uses it as the input to
	``get_reveal_type_output``:

	.. code-block:: python

	import os
	import pytest

	@pytest.fixture
	def _in_tmp_path(tmp_path):
	cur = os.getcwd()
	try:
	os.chdir(tmp_path)
	yield
	finally:
	os.chdir(cur)

	@pytest.fixture
	def run_reveal_type(tmp_path, _in_tmp_path):
	content_path = tmp_path / "reveal_type_test.py"

	def func(code_snippet, *, preamble = ""):
	content_path.write_text(preamble + f"reveal_type({code_snippet})")
	return get_reveal_type_output("reveal_type_test.py")

	return func


	For more details, see `the documentation on mypy.api
	<https://mypy.readthedocs.io/en/stable/extending_mypy.html#integrating-mypy-into-another-python-application>`_.

	pytest-mypy-plugins
	-------------------

	`pytest-mypy-plugins <https://github.com/typeddjango/pytest-mypy-plugins>`_ is
	a plugin for ``pytest`` which defines typing test cases as YAML data.
	The test cases are run through ``mypy`` and the output of ``reveal_type`` can
	be asserted.

	This project supports complex typing arrangements like ``pytest`` parametrized
	tests and per-test ``mypy`` configuration. It requires that you are using
	``pytest`` to run your tests, and runs ``mypy`` in a subprocess per test case.

	This is an example of a parametrized test with ``pytest-mypy-plugins``:

	.. code-block:: yaml

	- case: with_params
	parametrized:
	- val: 1
	rt: builtins.int
	- val: 1.0
	rt: builtins.float
	main: \|
	reveal_type({[ val }}) # N: Revealed type is '{{ rt }}'

	Improving Type Completeness
	===========================

	One of the goals of many libraries is to ensure that they are "fully type
	annotated", meaning that they provide complete and accurate type annotations
	for all functions, classes, and objects. Having full annotations is referred to
	as "type completeness" or "type coverage".

	Here are some tips for increasing the type completeness score for your
	library:

	- Make type completeness an output of your testing process. Several type
	checkers have options for generating useful output, warnings, or even
	reports.
	- If your package includes tests or sample code, consider removing them
	from the distribution. If there is good reason to include them,
	consider placing them in a directory that begins with an underscore
	so they are not considered part of your library’s interface.
	- If your package includes submodules that are meant to be
	implementation details, rename those files to begin with an
	underscore.
	- If a symbol is not intended to be part of the library’s interface and
	is considered an implementation detail, rename it such that it begins
	with an underscore. It will then be considered private and excluded
	from the type completeness check.
	- If your package exposes types from other libraries, work with the
	maintainers of these other libraries to achieve type completeness.

	.. warning::

	The ways in which different type checkers evaluate and help you achieve
	better type coverage may differ. Some of the above recommendations may or
	may not be helpful to you, depending on which type checking tools you use.

	``mypy`` disallow options
	-------------------------

	``mypy`` offers several options which can detect untyped code.
	More details can be found in `the mypy documentation on these options
	<https://mypy.readthedocs.io/en/latest/command_line.html#untyped-definitions-and-calls>`_.

	Some basic usages which make ``mypy`` error on untyped data are::

	mypy --disallow-untyped-defs
	mypy --disallow-incomplete-defs

	``pyright`` type verification
	-----------------------------

	pyright has a special command line flag, ``--verifytypes``, for verifying
	type completeness. You can learn more about it from
	`the pyright documentation on verifying type completeness
	<https://github.com/microsoft/pyright/blob/main/docs/typed-libraries.md#verifying-type-completeness>`_.

	``mypy`` reports
	----------------

	``mypy`` offers several options options for generating reports on its analysis.
	See `the mypy documentation on report generation
	<https://mypy.readthedocs.io/en/stable/command_line.html#report-generation>`_ for details.