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1316 lines
60 KiB
ReStructuredText
1316 lines
60 KiB
ReStructuredText
.. _glossary:
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********
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Glossary
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********
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.. if you add new entries, keep the alphabetical sorting!
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.. glossary::
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``>>>``
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The default Python prompt of the :term:`interactive` shell. Often
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seen for code examples which can be executed interactively in the
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interpreter.
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``...``
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Can refer to:
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* The default Python prompt of the :term:`interactive` shell when entering the
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code for an indented code block, when within a pair of matching left and
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right delimiters (parentheses, square brackets, curly braces or triple
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quotes), or after specifying a decorator.
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* The :const:`Ellipsis` built-in constant.
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abstract base class
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Abstract base classes complement :term:`duck-typing` by
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providing a way to define interfaces when other techniques like
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:func:`hasattr` would be clumsy or subtly wrong (for example with
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:ref:`magic methods <special-lookup>`). ABCs introduce virtual
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subclasses, which are classes that don't inherit from a class but are
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still recognized by :func:`isinstance` and :func:`issubclass`; see the
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:mod:`abc` module documentation. Python comes with many built-in ABCs for
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data structures (in the :mod:`collections.abc` module), numbers (in the
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:mod:`numbers` module), streams (in the :mod:`io` module), import finders
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and loaders (in the :mod:`importlib.abc` module). You can create your own
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ABCs with the :mod:`abc` module.
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annotation
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A label associated with a variable, a class
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attribute or a function parameter or return value,
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used by convention as a :term:`type hint`.
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Annotations of local variables cannot be accessed at runtime, but
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annotations of global variables, class attributes, and functions
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are stored in the :attr:`__annotations__`
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special attribute of modules, classes, and functions,
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respectively.
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See :term:`variable annotation`, :term:`function annotation`, :pep:`484`
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and :pep:`526`, which describe this functionality.
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Also see :ref:`annotations-howto`
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for best practices on working with annotations.
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argument
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A value passed to a :term:`function` (or :term:`method`) when calling the
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function. There are two kinds of argument:
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* :dfn:`keyword argument`: an argument preceded by an identifier (e.g.
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``name=``) in a function call or passed as a value in a dictionary
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preceded by ``**``. For example, ``3`` and ``5`` are both keyword
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arguments in the following calls to :func:`complex`::
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complex(real=3, imag=5)
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complex(**{'real': 3, 'imag': 5})
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* :dfn:`positional argument`: an argument that is not a keyword argument.
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Positional arguments can appear at the beginning of an argument list
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and/or be passed as elements of an :term:`iterable` preceded by ``*``.
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For example, ``3`` and ``5`` are both positional arguments in the
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following calls::
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complex(3, 5)
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complex(*(3, 5))
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Arguments are assigned to the named local variables in a function body.
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See the :ref:`calls` section for the rules governing this assignment.
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Syntactically, any expression can be used to represent an argument; the
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evaluated value is assigned to the local variable.
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See also the :term:`parameter` glossary entry, the FAQ question on
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:ref:`the difference between arguments and parameters
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<faq-argument-vs-parameter>`, and :pep:`362`.
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asynchronous context manager
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An object which controls the environment seen in an
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:keyword:`async with` statement by defining :meth:`~object.__aenter__` and
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:meth:`~object.__aexit__` methods. Introduced by :pep:`492`.
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asynchronous generator
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A function which returns an :term:`asynchronous generator iterator`. It
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looks like a coroutine function defined with :keyword:`async def` except
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that it contains :keyword:`yield` expressions for producing a series of
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values usable in an :keyword:`async for` loop.
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Usually refers to an asynchronous generator function, but may refer to an
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*asynchronous generator iterator* in some contexts. In cases where the
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intended meaning isn't clear, using the full terms avoids ambiguity.
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An asynchronous generator function may contain :keyword:`await`
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expressions as well as :keyword:`async for`, and :keyword:`async with`
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statements.
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asynchronous generator iterator
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An object created by a :term:`asynchronous generator` function.
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This is an :term:`asynchronous iterator` which when called using the
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:meth:`~object.__anext__` method returns an awaitable object which will execute
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the body of the asynchronous generator function until the next
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:keyword:`yield` expression.
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Each :keyword:`yield` temporarily suspends processing, remembering the
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location execution state (including local variables and pending
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try-statements). When the *asynchronous generator iterator* effectively
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resumes with another awaitable returned by :meth:`~object.__anext__`, it
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picks up where it left off. See :pep:`492` and :pep:`525`.
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asynchronous iterable
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An object, that can be used in an :keyword:`async for` statement.
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Must return an :term:`asynchronous iterator` from its
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:meth:`~object.__aiter__` method. Introduced by :pep:`492`.
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asynchronous iterator
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An object that implements the :meth:`~object.__aiter__` and :meth:`~object.__anext__`
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methods. :meth:`~object.__anext__` must return an :term:`awaitable` object.
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:keyword:`async for` resolves the awaitables returned by an asynchronous
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iterator's :meth:`~object.__anext__` method until it raises a
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:exc:`StopAsyncIteration` exception. Introduced by :pep:`492`.
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attribute
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A value associated with an object which is usually referenced by name
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using dotted expressions.
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For example, if an object *o* has an attribute
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*a* it would be referenced as *o.a*.
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It is possible to give an object an attribute whose name is not an
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identifier as defined by :ref:`identifiers`, for example using
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:func:`setattr`, if the object allows it.
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Such an attribute will not be accessible using a dotted expression,
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and would instead need to be retrieved with :func:`getattr`.
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awaitable
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An object that can be used in an :keyword:`await` expression. Can be
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a :term:`coroutine` or an object with an :meth:`~object.__await__` method.
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See also :pep:`492`.
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BDFL
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Benevolent Dictator For Life, a.k.a. `Guido van Rossum
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<https://gvanrossum.github.io/>`_, Python's creator.
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binary file
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A :term:`file object` able to read and write
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:term:`bytes-like objects <bytes-like object>`.
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Examples of binary files are files opened in binary mode (``'rb'``,
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``'wb'`` or ``'rb+'``), :data:`sys.stdin.buffer <sys.stdin>`,
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:data:`sys.stdout.buffer <sys.stdout>`, and instances of
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:class:`io.BytesIO` and :class:`gzip.GzipFile`.
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See also :term:`text file` for a file object able to read and write
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:class:`str` objects.
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borrowed reference
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In Python's C API, a borrowed reference is a reference to an object,
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where the code using the object does not own the reference.
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It becomes a dangling
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pointer if the object is destroyed. For example, a garbage collection can
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remove the last :term:`strong reference` to the object and so destroy it.
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Calling :c:func:`Py_INCREF` on the :term:`borrowed reference` is
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recommended to convert it to a :term:`strong reference` in-place, except
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when the object cannot be destroyed before the last usage of the borrowed
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reference. The :c:func:`Py_NewRef` function can be used to create a new
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:term:`strong reference`.
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bytes-like object
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An object that supports the :ref:`bufferobjects` and can
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export a C-:term:`contiguous` buffer. This includes all :class:`bytes`,
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:class:`bytearray`, and :class:`array.array` objects, as well as many
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common :class:`memoryview` objects. Bytes-like objects can
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be used for various operations that work with binary data; these include
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compression, saving to a binary file, and sending over a socket.
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Some operations need the binary data to be mutable. The documentation
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often refers to these as "read-write bytes-like objects". Example
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mutable buffer objects include :class:`bytearray` and a
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:class:`memoryview` of a :class:`bytearray`.
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Other operations require the binary data to be stored in
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immutable objects ("read-only bytes-like objects"); examples
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of these include :class:`bytes` and a :class:`memoryview`
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of a :class:`bytes` object.
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bytecode
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Python source code is compiled into bytecode, the internal representation
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of a Python program in the CPython interpreter. The bytecode is also
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cached in ``.pyc`` files so that executing the same file is
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faster the second time (recompilation from source to bytecode can be
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avoided). This "intermediate language" is said to run on a
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:term:`virtual machine` that executes the machine code corresponding to
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each bytecode. Do note that bytecodes are not expected to work between
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different Python virtual machines, nor to be stable between Python
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releases.
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A list of bytecode instructions can be found in the documentation for
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:ref:`the dis module <bytecodes>`.
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callable
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A callable is an object that can be called, possibly with a set
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of arguments (see :term:`argument`), with the following syntax::
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callable(argument1, argument2, argumentN)
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A :term:`function`, and by extension a :term:`method`, is a callable.
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An instance of a class that implements the :meth:`~object.__call__`
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method is also a callable.
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callback
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A subroutine function which is passed as an argument to be executed at
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some point in the future.
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class
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A template for creating user-defined objects. Class definitions
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normally contain method definitions which operate on instances of the
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class.
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class variable
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A variable defined in a class and intended to be modified only at
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class level (i.e., not in an instance of the class).
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complex number
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An extension of the familiar real number system in which all numbers are
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expressed as a sum of a real part and an imaginary part. Imaginary
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numbers are real multiples of the imaginary unit (the square root of
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``-1``), often written ``i`` in mathematics or ``j`` in
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engineering. Python has built-in support for complex numbers, which are
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written with this latter notation; the imaginary part is written with a
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``j`` suffix, e.g., ``3+1j``. To get access to complex equivalents of the
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:mod:`math` module, use :mod:`cmath`. Use of complex numbers is a fairly
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advanced mathematical feature. If you're not aware of a need for them,
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it's almost certain you can safely ignore them.
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context manager
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An object which controls the environment seen in a :keyword:`with`
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statement by defining :meth:`~object.__enter__` and :meth:`~object.__exit__` methods.
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See :pep:`343`.
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context variable
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A variable which can have different values depending on its context.
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This is similar to Thread-Local Storage in which each execution
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thread may have a different value for a variable. However, with context
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variables, there may be several contexts in one execution thread and the
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main usage for context variables is to keep track of variables in
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concurrent asynchronous tasks.
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See :mod:`contextvars`.
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contiguous
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.. index:: C-contiguous, Fortran contiguous
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A buffer is considered contiguous exactly if it is either
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*C-contiguous* or *Fortran contiguous*. Zero-dimensional buffers are
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C and Fortran contiguous. In one-dimensional arrays, the items
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must be laid out in memory next to each other, in order of
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increasing indexes starting from zero. In multidimensional
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C-contiguous arrays, the last index varies the fastest when
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visiting items in order of memory address. However, in
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Fortran contiguous arrays, the first index varies the fastest.
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coroutine
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Coroutines are a more generalized form of subroutines. Subroutines are
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entered at one point and exited at another point. Coroutines can be
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entered, exited, and resumed at many different points. They can be
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implemented with the :keyword:`async def` statement. See also
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:pep:`492`.
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coroutine function
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A function which returns a :term:`coroutine` object. A coroutine
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function may be defined with the :keyword:`async def` statement,
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and may contain :keyword:`await`, :keyword:`async for`, and
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:keyword:`async with` keywords. These were introduced
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by :pep:`492`.
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CPython
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The canonical implementation of the Python programming language, as
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distributed on `python.org <https://www.python.org>`_. The term "CPython"
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is used when necessary to distinguish this implementation from others
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such as Jython or IronPython.
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decorator
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A function returning another function, usually applied as a function
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transformation using the ``@wrapper`` syntax. Common examples for
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decorators are :func:`classmethod` and :func:`staticmethod`.
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The decorator syntax is merely syntactic sugar, the following two
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function definitions are semantically equivalent::
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def f(arg):
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...
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f = staticmethod(f)
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@staticmethod
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def f(arg):
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...
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The same concept exists for classes, but is less commonly used there. See
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the documentation for :ref:`function definitions <function>` and
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:ref:`class definitions <class>` for more about decorators.
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descriptor
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Any object which defines the methods :meth:`~object.__get__`,
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:meth:`~object.__set__`, or :meth:`~object.__delete__`.
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When a class attribute is a descriptor, its special
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binding behavior is triggered upon attribute lookup. Normally, using
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*a.b* to get, set or delete an attribute looks up the object named *b* in
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the class dictionary for *a*, but if *b* is a descriptor, the respective
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descriptor method gets called. Understanding descriptors is a key to a
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deep understanding of Python because they are the basis for many features
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including functions, methods, properties, class methods, static methods,
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and reference to super classes.
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For more information about descriptors' methods, see :ref:`descriptors`
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or the :ref:`Descriptor How To Guide <descriptorhowto>`.
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dictionary
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An associative array, where arbitrary keys are mapped to values. The
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keys can be any object with :meth:`~object.__hash__` and
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:meth:`~object.__eq__` methods.
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Called a hash in Perl.
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dictionary comprehension
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A compact way to process all or part of the elements in an iterable and
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return a dictionary with the results. ``results = {n: n ** 2 for n in
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range(10)}`` generates a dictionary containing key ``n`` mapped to
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value ``n ** 2``. See :ref:`comprehensions`.
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dictionary view
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The objects returned from :meth:`dict.keys`, :meth:`dict.values`, and
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:meth:`dict.items` are called dictionary views. They provide a dynamic
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view on the dictionary’s entries, which means that when the dictionary
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changes, the view reflects these changes. To force the
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dictionary view to become a full list use ``list(dictview)``. See
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:ref:`dict-views`.
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docstring
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A string literal which appears as the first expression in a class,
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function or module. While ignored when the suite is executed, it is
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recognized by the compiler and put into the :attr:`!__doc__` attribute
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of the enclosing class, function or module. Since it is available via
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introspection, it is the canonical place for documentation of the
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object.
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duck-typing
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A programming style which does not look at an object's type to determine
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if it has the right interface; instead, the method or attribute is simply
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called or used ("If it looks like a duck and quacks like a duck, it
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must be a duck.") By emphasizing interfaces rather than specific types,
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well-designed code improves its flexibility by allowing polymorphic
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substitution. Duck-typing avoids tests using :func:`type` or
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:func:`isinstance`. (Note, however, that duck-typing can be complemented
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with :term:`abstract base classes <abstract base class>`.) Instead, it
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typically employs :func:`hasattr` tests or :term:`EAFP` programming.
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EAFP
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Easier to ask for forgiveness than permission. This common Python coding
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style assumes the existence of valid keys or attributes and catches
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exceptions if the assumption proves false. This clean and fast style is
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characterized by the presence of many :keyword:`try` and :keyword:`except`
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statements. The technique contrasts with the :term:`LBYL` style
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common to many other languages such as C.
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expression
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A piece of syntax which can be evaluated to some value. In other words,
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an expression is an accumulation of expression elements like literals,
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names, attribute access, operators or function calls which all return a
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value. In contrast to many other languages, not all language constructs
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are expressions. There are also :term:`statement`\s which cannot be used
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as expressions, such as :keyword:`while`. Assignments are also statements,
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not expressions.
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extension module
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A module written in C or C++, using Python's C API to interact with the
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core and with user code.
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f-string
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String literals prefixed with ``'f'`` or ``'F'`` are commonly called
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"f-strings" which is short for
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:ref:`formatted string literals <f-strings>`. See also :pep:`498`.
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file object
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An object exposing a file-oriented API (with methods such as
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:meth:`!read` or :meth:`!write`) to an underlying resource. Depending
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on the way it was created, a file object can mediate access to a real
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on-disk file or to another type of storage or communication device
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(for example standard input/output, in-memory buffers, sockets, pipes,
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etc.). File objects are also called :dfn:`file-like objects` or
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:dfn:`streams`.
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There are actually three categories of file objects: raw
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:term:`binary files <binary file>`, buffered
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:term:`binary files <binary file>` and :term:`text files <text file>`.
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Their interfaces are defined in the :mod:`io` module. The canonical
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way to create a file object is by using the :func:`open` function.
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file-like object
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A synonym for :term:`file object`.
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filesystem encoding and error handler
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Encoding and error handler used by Python to decode bytes from the
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operating system and encode Unicode to the operating system.
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The filesystem encoding must guarantee to successfully decode all bytes
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below 128. If the file system encoding fails to provide this guarantee,
|
||
API functions can raise :exc:`UnicodeError`.
|
||
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The :func:`sys.getfilesystemencoding` and
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||
:func:`sys.getfilesystemencodeerrors` functions can be used to get the
|
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filesystem encoding and error handler.
|
||
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||
The :term:`filesystem encoding and error handler` are configured at
|
||
Python startup by the :c:func:`PyConfig_Read` function: see
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:c:member:`~PyConfig.filesystem_encoding` and
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||
:c:member:`~PyConfig.filesystem_errors` members of :c:type:`PyConfig`.
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||
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See also the :term:`locale encoding`.
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||
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||
finder
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||
An object that tries to find the :term:`loader` for a module that is
|
||
being imported.
|
||
|
||
There are two types of finder: :term:`meta path finders
|
||
<meta path finder>` for use with :data:`sys.meta_path`, and :term:`path
|
||
entry finders <path entry finder>` for use with :data:`sys.path_hooks`.
|
||
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||
See :ref:`importsystem` and :mod:`importlib` for much more detail.
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||
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floor division
|
||
Mathematical division that rounds down to nearest integer. The floor
|
||
division operator is ``//``. For example, the expression ``11 // 4``
|
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evaluates to ``2`` in contrast to the ``2.75`` returned by float true
|
||
division. Note that ``(-11) // 4`` is ``-3`` because that is ``-2.75``
|
||
rounded *downward*. See :pep:`238`.
|
||
|
||
free threading
|
||
A threading model where multiple threads can run Python bytecode
|
||
simultaneously within the same interpreter. This is in contrast to
|
||
the :term:`global interpreter lock` which allows only one thread to
|
||
execute Python bytecode at a time. See :pep:`703`.
|
||
|
||
function
|
||
A series of statements which returns some value to a caller. It can also
|
||
be passed zero or more :term:`arguments <argument>` which may be used in
|
||
the execution of the body. See also :term:`parameter`, :term:`method`,
|
||
and the :ref:`function` section.
|
||
|
||
function annotation
|
||
An :term:`annotation` of a function parameter or return value.
|
||
|
||
Function annotations are usually used for
|
||
:term:`type hints <type hint>`: for example, this function is expected to take two
|
||
:class:`int` arguments and is also expected to have an :class:`int`
|
||
return value::
|
||
|
||
def sum_two_numbers(a: int, b: int) -> int:
|
||
return a + b
|
||
|
||
Function annotation syntax is explained in section :ref:`function`.
|
||
|
||
See :term:`variable annotation` and :pep:`484`,
|
||
which describe this functionality.
|
||
Also see :ref:`annotations-howto`
|
||
for best practices on working with annotations.
|
||
|
||
__future__
|
||
A :ref:`future statement <future>`, ``from __future__ import <feature>``,
|
||
directs the compiler to compile the current module using syntax or
|
||
semantics that will become standard in a future release of Python.
|
||
The :mod:`__future__` module documents the possible values of
|
||
*feature*. By importing this module and evaluating its variables,
|
||
you can see when a new feature was first added to the language and
|
||
when it will (or did) become the default::
|
||
|
||
>>> import __future__
|
||
>>> __future__.division
|
||
_Feature((2, 2, 0, 'alpha', 2), (3, 0, 0, 'alpha', 0), 8192)
|
||
|
||
garbage collection
|
||
The process of freeing memory when it is not used anymore. Python
|
||
performs garbage collection via reference counting and a cyclic garbage
|
||
collector that is able to detect and break reference cycles. The
|
||
garbage collector can be controlled using the :mod:`gc` module.
|
||
|
||
.. index:: single: generator
|
||
|
||
generator
|
||
A function which returns a :term:`generator iterator`. It looks like a
|
||
normal function except that it contains :keyword:`yield` expressions
|
||
for producing a series of values usable in a for-loop or that can be
|
||
retrieved one at a time with the :func:`next` function.
|
||
|
||
Usually refers to a generator function, but may refer to a
|
||
*generator iterator* in some contexts. In cases where the intended
|
||
meaning isn't clear, using the full terms avoids ambiguity.
|
||
|
||
generator iterator
|
||
An object created by a :term:`generator` function.
|
||
|
||
Each :keyword:`yield` temporarily suspends processing, remembering the
|
||
location execution state (including local variables and pending
|
||
try-statements). When the *generator iterator* resumes, it picks up where
|
||
it left off (in contrast to functions which start fresh on every
|
||
invocation).
|
||
|
||
.. index:: single: generator expression
|
||
|
||
generator expression
|
||
An :term:`expression` that returns an :term:`iterator`. It looks like a normal expression
|
||
followed by a :keyword:`!for` clause defining a loop variable, range,
|
||
and an optional :keyword:`!if` clause. The combined expression
|
||
generates values for an enclosing function::
|
||
|
||
>>> sum(i*i for i in range(10)) # sum of squares 0, 1, 4, ... 81
|
||
285
|
||
|
||
generic function
|
||
A function composed of multiple functions implementing the same operation
|
||
for different types. Which implementation should be used during a call is
|
||
determined by the dispatch algorithm.
|
||
|
||
See also the :term:`single dispatch` glossary entry, the
|
||
:func:`functools.singledispatch` decorator, and :pep:`443`.
|
||
|
||
generic type
|
||
A :term:`type` that can be parameterized; typically a
|
||
:ref:`container class<sequence-types>` such as :class:`list` or
|
||
:class:`dict`. Used for :term:`type hints <type hint>` and
|
||
:term:`annotations <annotation>`.
|
||
|
||
For more details, see :ref:`generic alias types<types-genericalias>`,
|
||
:pep:`483`, :pep:`484`, :pep:`585`, and the :mod:`typing` module.
|
||
|
||
GIL
|
||
See :term:`global interpreter lock`.
|
||
|
||
global interpreter lock
|
||
The mechanism used by the :term:`CPython` interpreter to assure that
|
||
only one thread executes Python :term:`bytecode` at a time.
|
||
This simplifies the CPython implementation by making the object model
|
||
(including critical built-in types such as :class:`dict`) implicitly
|
||
safe against concurrent access. Locking the entire interpreter
|
||
makes it easier for the interpreter to be multi-threaded, at the
|
||
expense of much of the parallelism afforded by multi-processor
|
||
machines.
|
||
|
||
However, some extension modules, either standard or third-party,
|
||
are designed so as to release the GIL when doing computationally intensive
|
||
tasks such as compression or hashing. Also, the GIL is always released
|
||
when doing I/O.
|
||
|
||
As of Python 3.13, the GIL can be disabled using the :option:`--disable-gil`
|
||
build configuration. After building Python with this option, code must be
|
||
run with :option:`-X gil 0 <-X>` or after setting the :envvar:`PYTHON_GIL=0 <PYTHON_GIL>`
|
||
environment variable. This feature enables improved performance for
|
||
multi-threaded applications and makes it easier to use multi-core CPUs
|
||
efficiently. For more details, see :pep:`703`.
|
||
|
||
hash-based pyc
|
||
A bytecode cache file that uses the hash rather than the last-modified
|
||
time of the corresponding source file to determine its validity. See
|
||
:ref:`pyc-invalidation`.
|
||
|
||
hashable
|
||
An object is *hashable* if it has a hash value which never changes during
|
||
its lifetime (it needs a :meth:`~object.__hash__` method), and can be
|
||
compared to other objects (it needs an :meth:`~object.__eq__` method).
|
||
Hashable objects which
|
||
compare equal must have the same hash value.
|
||
|
||
Hashability makes an object usable as a dictionary key and a set member,
|
||
because these data structures use the hash value internally.
|
||
|
||
Most of Python's immutable built-in objects are hashable; mutable
|
||
containers (such as lists or dictionaries) are not; immutable
|
||
containers (such as tuples and frozensets) are only hashable if
|
||
their elements are hashable. Objects which are
|
||
instances of user-defined classes are hashable by default. They all
|
||
compare unequal (except with themselves), and their hash value is derived
|
||
from their :func:`id`.
|
||
|
||
IDLE
|
||
An Integrated Development and Learning Environment for Python.
|
||
:ref:`idle` is a basic editor and interpreter environment
|
||
which ships with the standard distribution of Python.
|
||
|
||
immortal
|
||
If an object is immortal, its reference count is never modified, and
|
||
therefore it is never deallocated.
|
||
|
||
Built-in strings and singletons are immortal objects. For example,
|
||
:const:`True` and :const:`None` singletons are immortal.
|
||
|
||
See `PEP 683 – Immortal Objects, Using a Fixed Refcount
|
||
<https://peps.python.org/pep-0683/>`_ for more information.
|
||
|
||
immutable
|
||
An object with a fixed value. Immutable objects include numbers, strings and
|
||
tuples. Such an object cannot be altered. A new object has to
|
||
be created if a different value has to be stored. They play an important
|
||
role in places where a constant hash value is needed, for example as a key
|
||
in a dictionary.
|
||
|
||
import path
|
||
A list of locations (or :term:`path entries <path entry>`) that are
|
||
searched by the :term:`path based finder` for modules to import. During
|
||
import, this list of locations usually comes from :data:`sys.path`, but
|
||
for subpackages it may also come from the parent package's ``__path__``
|
||
attribute.
|
||
|
||
importing
|
||
The process by which Python code in one module is made available to
|
||
Python code in another module.
|
||
|
||
importer
|
||
An object that both finds and loads a module; both a
|
||
:term:`finder` and :term:`loader` object.
|
||
|
||
interactive
|
||
Python has an interactive interpreter which means you can enter
|
||
statements and expressions at the interpreter prompt, immediately
|
||
execute them and see their results. Just launch ``python`` with no
|
||
arguments (possibly by selecting it from your computer's main
|
||
menu). It is a very powerful way to test out new ideas or inspect
|
||
modules and packages (remember ``help(x)``). For more on interactive
|
||
mode, see :ref:`tut-interac`.
|
||
|
||
interpreted
|
||
Python is an interpreted language, as opposed to a compiled one,
|
||
though the distinction can be blurry because of the presence of the
|
||
bytecode compiler. This means that source files can be run directly
|
||
without explicitly creating an executable which is then run.
|
||
Interpreted languages typically have a shorter development/debug cycle
|
||
than compiled ones, though their programs generally also run more
|
||
slowly. See also :term:`interactive`.
|
||
|
||
interpreter shutdown
|
||
When asked to shut down, the Python interpreter enters a special phase
|
||
where it gradually releases all allocated resources, such as modules
|
||
and various critical internal structures. It also makes several calls
|
||
to the :term:`garbage collector <garbage collection>`. This can trigger
|
||
the execution of code in user-defined destructors or weakref callbacks.
|
||
Code executed during the shutdown phase can encounter various
|
||
exceptions as the resources it relies on may not function anymore
|
||
(common examples are library modules or the warnings machinery).
|
||
|
||
The main reason for interpreter shutdown is that the ``__main__`` module
|
||
or the script being run has finished executing.
|
||
|
||
iterable
|
||
An object capable of returning its members one at a time. Examples of
|
||
iterables include all sequence types (such as :class:`list`, :class:`str`,
|
||
and :class:`tuple`) and some non-sequence types like :class:`dict`,
|
||
:term:`file objects <file object>`, and objects of any classes you define
|
||
with an :meth:`~iterator.__iter__` method or with a
|
||
:meth:`~object.__getitem__` method
|
||
that implements :term:`sequence` semantics.
|
||
|
||
Iterables can be
|
||
used in a :keyword:`for` loop and in many other places where a sequence is
|
||
needed (:func:`zip`, :func:`map`, ...). When an iterable object is passed
|
||
as an argument to the built-in function :func:`iter`, it returns an
|
||
iterator for the object. This iterator is good for one pass over the set
|
||
of values. When using iterables, it is usually not necessary to call
|
||
:func:`iter` or deal with iterator objects yourself. The :keyword:`for`
|
||
statement does that automatically for you, creating a temporary unnamed
|
||
variable to hold the iterator for the duration of the loop. See also
|
||
:term:`iterator`, :term:`sequence`, and :term:`generator`.
|
||
|
||
iterator
|
||
An object representing a stream of data. Repeated calls to the iterator's
|
||
:meth:`~iterator.__next__` method (or passing it to the built-in function
|
||
:func:`next`) return successive items in the stream. When no more data
|
||
are available a :exc:`StopIteration` exception is raised instead. At this
|
||
point, the iterator object is exhausted and any further calls to its
|
||
:meth:`!__next__` method just raise :exc:`StopIteration` again. Iterators
|
||
are required to have an :meth:`~iterator.__iter__` method that returns the iterator
|
||
object itself so every iterator is also iterable and may be used in most
|
||
places where other iterables are accepted. One notable exception is code
|
||
which attempts multiple iteration passes. A container object (such as a
|
||
:class:`list`) produces a fresh new iterator each time you pass it to the
|
||
:func:`iter` function or use it in a :keyword:`for` loop. Attempting this
|
||
with an iterator will just return the same exhausted iterator object used
|
||
in the previous iteration pass, making it appear like an empty container.
|
||
|
||
More information can be found in :ref:`typeiter`.
|
||
|
||
.. impl-detail::
|
||
|
||
CPython does not consistently apply the requirement that an iterator
|
||
define :meth:`~iterator.__iter__`.
|
||
And also please note that the free-threading CPython does not guarantee
|
||
the thread-safety of iterator operations.
|
||
|
||
|
||
key function
|
||
A key function or collation function is a callable that returns a value
|
||
used for sorting or ordering. For example, :func:`locale.strxfrm` is
|
||
used to produce a sort key that is aware of locale specific sort
|
||
conventions.
|
||
|
||
A number of tools in Python accept key functions to control how elements
|
||
are ordered or grouped. They include :func:`min`, :func:`max`,
|
||
:func:`sorted`, :meth:`list.sort`, :func:`heapq.merge`,
|
||
:func:`heapq.nsmallest`, :func:`heapq.nlargest`, and
|
||
:func:`itertools.groupby`.
|
||
|
||
There are several ways to create a key function. For example. the
|
||
:meth:`str.lower` method can serve as a key function for case insensitive
|
||
sorts. Alternatively, a key function can be built from a
|
||
:keyword:`lambda` expression such as ``lambda r: (r[0], r[2])``. Also,
|
||
:func:`operator.attrgetter`, :func:`operator.itemgetter`, and
|
||
:func:`operator.methodcaller` are three key function constructors. See the :ref:`Sorting HOW TO
|
||
<sortinghowto>` for examples of how to create and use key functions.
|
||
|
||
keyword argument
|
||
See :term:`argument`.
|
||
|
||
lambda
|
||
An anonymous inline function consisting of a single :term:`expression`
|
||
which is evaluated when the function is called. The syntax to create
|
||
a lambda function is ``lambda [parameters]: expression``
|
||
|
||
LBYL
|
||
Look before you leap. This coding style explicitly tests for
|
||
pre-conditions before making calls or lookups. This style contrasts with
|
||
the :term:`EAFP` approach and is characterized by the presence of many
|
||
:keyword:`if` statements.
|
||
|
||
In a multi-threaded environment, the LBYL approach can risk introducing a
|
||
race condition between "the looking" and "the leaping". For example, the
|
||
code, ``if key in mapping: return mapping[key]`` can fail if another
|
||
thread removes *key* from *mapping* after the test, but before the lookup.
|
||
This issue can be solved with locks or by using the EAFP approach.
|
||
|
||
list
|
||
A built-in Python :term:`sequence`. Despite its name it is more akin
|
||
to an array in other languages than to a linked list since access to
|
||
elements is *O*\ (1).
|
||
|
||
list comprehension
|
||
A compact way to process all or part of the elements in a sequence and
|
||
return a list with the results. ``result = ['{:#04x}'.format(x) for x in
|
||
range(256) if x % 2 == 0]`` generates a list of strings containing
|
||
even hex numbers (0x..) in the range from 0 to 255. The :keyword:`if`
|
||
clause is optional. If omitted, all elements in ``range(256)`` are
|
||
processed.
|
||
|
||
loader
|
||
An object that loads a module. It must define a method named
|
||
:meth:`load_module`. A loader is typically returned by a
|
||
:term:`finder`. See :pep:`302` for details and
|
||
:class:`importlib.abc.Loader` for an :term:`abstract base class`.
|
||
|
||
locale encoding
|
||
On Unix, it is the encoding of the LC_CTYPE locale. It can be set with
|
||
:func:`locale.setlocale(locale.LC_CTYPE, new_locale) <locale.setlocale>`.
|
||
|
||
On Windows, it is the ANSI code page (ex: ``"cp1252"``).
|
||
|
||
On Android and VxWorks, Python uses ``"utf-8"`` as the locale encoding.
|
||
|
||
:func:`locale.getencoding` can be used to get the locale encoding.
|
||
|
||
See also the :term:`filesystem encoding and error handler`.
|
||
|
||
magic method
|
||
.. index:: pair: magic; method
|
||
|
||
An informal synonym for :term:`special method`.
|
||
|
||
mapping
|
||
A container object that supports arbitrary key lookups and implements the
|
||
methods specified in the :class:`collections.abc.Mapping` or
|
||
:class:`collections.abc.MutableMapping`
|
||
:ref:`abstract base classes <collections-abstract-base-classes>`. Examples
|
||
include :class:`dict`, :class:`collections.defaultdict`,
|
||
:class:`collections.OrderedDict` and :class:`collections.Counter`.
|
||
|
||
meta path finder
|
||
A :term:`finder` returned by a search of :data:`sys.meta_path`. Meta path
|
||
finders are related to, but different from :term:`path entry finders
|
||
<path entry finder>`.
|
||
|
||
See :class:`importlib.abc.MetaPathFinder` for the methods that meta path
|
||
finders implement.
|
||
|
||
metaclass
|
||
The class of a class. Class definitions create a class name, a class
|
||
dictionary, and a list of base classes. The metaclass is responsible for
|
||
taking those three arguments and creating the class. Most object oriented
|
||
programming languages provide a default implementation. What makes Python
|
||
special is that it is possible to create custom metaclasses. Most users
|
||
never need this tool, but when the need arises, metaclasses can provide
|
||
powerful, elegant solutions. They have been used for logging attribute
|
||
access, adding thread-safety, tracking object creation, implementing
|
||
singletons, and many other tasks.
|
||
|
||
More information can be found in :ref:`metaclasses`.
|
||
|
||
method
|
||
A function which is defined inside a class body. If called as an attribute
|
||
of an instance of that class, the method will get the instance object as
|
||
its first :term:`argument` (which is usually called ``self``).
|
||
See :term:`function` and :term:`nested scope`.
|
||
|
||
method resolution order
|
||
Method Resolution Order is the order in which base classes are searched
|
||
for a member during lookup. See :ref:`python_2.3_mro` for details of the
|
||
algorithm used by the Python interpreter since the 2.3 release.
|
||
|
||
module
|
||
An object that serves as an organizational unit of Python code. Modules
|
||
have a namespace containing arbitrary Python objects. Modules are loaded
|
||
into Python by the process of :term:`importing`.
|
||
|
||
See also :term:`package`.
|
||
|
||
module spec
|
||
A namespace containing the import-related information used to load a
|
||
module. An instance of :class:`importlib.machinery.ModuleSpec`.
|
||
|
||
MRO
|
||
See :term:`method resolution order`.
|
||
|
||
mutable
|
||
Mutable objects can change their value but keep their :func:`id`. See
|
||
also :term:`immutable`.
|
||
|
||
named tuple
|
||
The term "named tuple" applies to any type or class that inherits from
|
||
tuple and whose indexable elements are also accessible using named
|
||
attributes. The type or class may have other features as well.
|
||
|
||
Several built-in types are named tuples, including the values returned
|
||
by :func:`time.localtime` and :func:`os.stat`. Another example is
|
||
:data:`sys.float_info`::
|
||
|
||
>>> sys.float_info[1] # indexed access
|
||
1024
|
||
>>> sys.float_info.max_exp # named field access
|
||
1024
|
||
>>> isinstance(sys.float_info, tuple) # kind of tuple
|
||
True
|
||
|
||
Some named tuples are built-in types (such as the above examples).
|
||
Alternatively, a named tuple can be created from a regular class
|
||
definition that inherits from :class:`tuple` and that defines named
|
||
fields. Such a class can be written by hand, or it can be created by
|
||
inheriting :class:`typing.NamedTuple`, or with the factory function
|
||
:func:`collections.namedtuple`. The latter techniques also add some
|
||
extra methods that may not be found in hand-written or built-in named
|
||
tuples.
|
||
|
||
namespace
|
||
The place where a variable is stored. Namespaces are implemented as
|
||
dictionaries. There are the local, global and built-in namespaces as well
|
||
as nested namespaces in objects (in methods). Namespaces support
|
||
modularity by preventing naming conflicts. For instance, the functions
|
||
:func:`builtins.open <.open>` and :func:`os.open` are distinguished by
|
||
their namespaces. Namespaces also aid readability and maintainability by
|
||
making it clear which module implements a function. For instance, writing
|
||
:func:`random.seed` or :func:`itertools.islice` makes it clear that those
|
||
functions are implemented by the :mod:`random` and :mod:`itertools`
|
||
modules, respectively.
|
||
|
||
namespace package
|
||
A :pep:`420` :term:`package` which serves only as a container for
|
||
subpackages. Namespace packages may have no physical representation,
|
||
and specifically are not like a :term:`regular package` because they
|
||
have no ``__init__.py`` file.
|
||
|
||
See also :term:`module`.
|
||
|
||
nested scope
|
||
The ability to refer to a variable in an enclosing definition. For
|
||
instance, a function defined inside another function can refer to
|
||
variables in the outer function. Note that nested scopes by default work
|
||
only for reference and not for assignment. Local variables both read and
|
||
write in the innermost scope. Likewise, global variables read and write
|
||
to the global namespace. The :keyword:`nonlocal` allows writing to outer
|
||
scopes.
|
||
|
||
new-style class
|
||
Old name for the flavor of classes now used for all class objects. In
|
||
earlier Python versions, only new-style classes could use Python's newer,
|
||
versatile features like :attr:`~object.__slots__`, descriptors,
|
||
properties, :meth:`~object.__getattribute__`, class methods, and static
|
||
methods.
|
||
|
||
object
|
||
Any data with state (attributes or value) and defined behavior
|
||
(methods). Also the ultimate base class of any :term:`new-style
|
||
class`.
|
||
|
||
optimized scope
|
||
A scope where target local variable names are reliably known to the
|
||
compiler when the code is compiled, allowing optimization of read and
|
||
write access to these names. The local namespaces for functions,
|
||
generators, coroutines, comprehensions, and generator expressions are
|
||
optimized in this fashion. Note: most interpreter optimizations are
|
||
applied to all scopes, only those relying on a known set of local
|
||
and nonlocal variable names are restricted to optimized scopes.
|
||
|
||
package
|
||
A Python :term:`module` which can contain submodules or recursively,
|
||
subpackages. Technically, a package is a Python module with a
|
||
``__path__`` attribute.
|
||
|
||
See also :term:`regular package` and :term:`namespace package`.
|
||
|
||
parameter
|
||
A named entity in a :term:`function` (or method) definition that
|
||
specifies an :term:`argument` (or in some cases, arguments) that the
|
||
function can accept. There are five kinds of parameter:
|
||
|
||
* :dfn:`positional-or-keyword`: specifies an argument that can be passed
|
||
either :term:`positionally <argument>` or as a :term:`keyword argument
|
||
<argument>`. This is the default kind of parameter, for example *foo*
|
||
and *bar* in the following::
|
||
|
||
def func(foo, bar=None): ...
|
||
|
||
.. _positional-only_parameter:
|
||
|
||
* :dfn:`positional-only`: specifies an argument that can be supplied only
|
||
by position. Positional-only parameters can be defined by including a
|
||
``/`` character in the parameter list of the function definition after
|
||
them, for example *posonly1* and *posonly2* in the following::
|
||
|
||
def func(posonly1, posonly2, /, positional_or_keyword): ...
|
||
|
||
.. _keyword-only_parameter:
|
||
|
||
* :dfn:`keyword-only`: specifies an argument that can be supplied only
|
||
by keyword. Keyword-only parameters can be defined by including a
|
||
single var-positional parameter or bare ``*`` in the parameter list
|
||
of the function definition before them, for example *kw_only1* and
|
||
*kw_only2* in the following::
|
||
|
||
def func(arg, *, kw_only1, kw_only2): ...
|
||
|
||
* :dfn:`var-positional`: specifies that an arbitrary sequence of
|
||
positional arguments can be provided (in addition to any positional
|
||
arguments already accepted by other parameters). Such a parameter can
|
||
be defined by prepending the parameter name with ``*``, for example
|
||
*args* in the following::
|
||
|
||
def func(*args, **kwargs): ...
|
||
|
||
* :dfn:`var-keyword`: specifies that arbitrarily many keyword arguments
|
||
can be provided (in addition to any keyword arguments already accepted
|
||
by other parameters). Such a parameter can be defined by prepending
|
||
the parameter name with ``**``, for example *kwargs* in the example
|
||
above.
|
||
|
||
Parameters can specify both optional and required arguments, as well as
|
||
default values for some optional arguments.
|
||
|
||
See also the :term:`argument` glossary entry, the FAQ question on
|
||
:ref:`the difference between arguments and parameters
|
||
<faq-argument-vs-parameter>`, the :class:`inspect.Parameter` class, the
|
||
:ref:`function` section, and :pep:`362`.
|
||
|
||
path entry
|
||
A single location on the :term:`import path` which the :term:`path
|
||
based finder` consults to find modules for importing.
|
||
|
||
path entry finder
|
||
A :term:`finder` returned by a callable on :data:`sys.path_hooks`
|
||
(i.e. a :term:`path entry hook`) which knows how to locate modules given
|
||
a :term:`path entry`.
|
||
|
||
See :class:`importlib.abc.PathEntryFinder` for the methods that path entry
|
||
finders implement.
|
||
|
||
path entry hook
|
||
A callable on the :data:`sys.path_hooks` list which returns a :term:`path
|
||
entry finder` if it knows how to find modules on a specific :term:`path
|
||
entry`.
|
||
|
||
path based finder
|
||
One of the default :term:`meta path finders <meta path finder>` which
|
||
searches an :term:`import path` for modules.
|
||
|
||
path-like object
|
||
An object representing a file system path. A path-like object is either
|
||
a :class:`str` or :class:`bytes` object representing a path, or an object
|
||
implementing the :class:`os.PathLike` protocol. An object that supports
|
||
the :class:`os.PathLike` protocol can be converted to a :class:`str` or
|
||
:class:`bytes` file system path by calling the :func:`os.fspath` function;
|
||
:func:`os.fsdecode` and :func:`os.fsencode` can be used to guarantee a
|
||
:class:`str` or :class:`bytes` result instead, respectively. Introduced
|
||
by :pep:`519`.
|
||
|
||
PEP
|
||
Python Enhancement Proposal. A PEP is a design document
|
||
providing information to the Python community, or describing a new
|
||
feature for Python or its processes or environment. PEPs should
|
||
provide a concise technical specification and a rationale for proposed
|
||
features.
|
||
|
||
PEPs are intended to be the primary mechanisms for proposing major new
|
||
features, for collecting community input on an issue, and for documenting
|
||
the design decisions that have gone into Python. The PEP author is
|
||
responsible for building consensus within the community and documenting
|
||
dissenting opinions.
|
||
|
||
See :pep:`1`.
|
||
|
||
portion
|
||
A set of files in a single directory (possibly stored in a zip file)
|
||
that contribute to a namespace package, as defined in :pep:`420`.
|
||
|
||
positional argument
|
||
See :term:`argument`.
|
||
|
||
provisional API
|
||
A provisional API is one which has been deliberately excluded from
|
||
the standard library's backwards compatibility guarantees. While major
|
||
changes to such interfaces are not expected, as long as they are marked
|
||
provisional, backwards incompatible changes (up to and including removal
|
||
of the interface) may occur if deemed necessary by core developers. Such
|
||
changes will not be made gratuitously -- they will occur only if serious
|
||
fundamental flaws are uncovered that were missed prior to the inclusion
|
||
of the API.
|
||
|
||
Even for provisional APIs, backwards incompatible changes are seen as
|
||
a "solution of last resort" - every attempt will still be made to find
|
||
a backwards compatible resolution to any identified problems.
|
||
|
||
This process allows the standard library to continue to evolve over
|
||
time, without locking in problematic design errors for extended periods
|
||
of time. See :pep:`411` for more details.
|
||
|
||
provisional package
|
||
See :term:`provisional API`.
|
||
|
||
Python 3000
|
||
Nickname for the Python 3.x release line (coined long ago when the
|
||
release of version 3 was something in the distant future.) This is also
|
||
abbreviated "Py3k".
|
||
|
||
Pythonic
|
||
An idea or piece of code which closely follows the most common idioms
|
||
of the Python language, rather than implementing code using concepts
|
||
common to other languages. For example, a common idiom in Python is
|
||
to loop over all elements of an iterable using a :keyword:`for`
|
||
statement. Many other languages don't have this type of construct, so
|
||
people unfamiliar with Python sometimes use a numerical counter instead::
|
||
|
||
for i in range(len(food)):
|
||
print(food[i])
|
||
|
||
As opposed to the cleaner, Pythonic method::
|
||
|
||
for piece in food:
|
||
print(piece)
|
||
|
||
qualified name
|
||
A dotted name showing the "path" from a module's global scope to a
|
||
class, function or method defined in that module, as defined in
|
||
:pep:`3155`. For top-level functions and classes, the qualified name
|
||
is the same as the object's name::
|
||
|
||
>>> class C:
|
||
... class D:
|
||
... def meth(self):
|
||
... pass
|
||
...
|
||
>>> C.__qualname__
|
||
'C'
|
||
>>> C.D.__qualname__
|
||
'C.D'
|
||
>>> C.D.meth.__qualname__
|
||
'C.D.meth'
|
||
|
||
When used to refer to modules, the *fully qualified name* means the
|
||
entire dotted path to the module, including any parent packages,
|
||
e.g. ``email.mime.text``::
|
||
|
||
>>> import email.mime.text
|
||
>>> email.mime.text.__name__
|
||
'email.mime.text'
|
||
|
||
reference count
|
||
The number of references to an object. When the reference count of an
|
||
object drops to zero, it is deallocated. Some objects are
|
||
:term:`immortal` and have reference counts that are never modified, and
|
||
therefore the objects are never deallocated. Reference counting is
|
||
generally not visible to Python code, but it is a key element of the
|
||
:term:`CPython` implementation. Programmers can call the
|
||
:func:`sys.getrefcount` function to return the
|
||
reference count for a particular object.
|
||
|
||
regular package
|
||
A traditional :term:`package`, such as a directory containing an
|
||
``__init__.py`` file.
|
||
|
||
See also :term:`namespace package`.
|
||
|
||
REPL
|
||
An acronym for the "read–eval–print loop", another name for the
|
||
:term:`interactive` interpreter shell.
|
||
|
||
__slots__
|
||
A declaration inside a class that saves memory by pre-declaring space for
|
||
instance attributes and eliminating instance dictionaries. Though
|
||
popular, the technique is somewhat tricky to get right and is best
|
||
reserved for rare cases where there are large numbers of instances in a
|
||
memory-critical application.
|
||
|
||
sequence
|
||
An :term:`iterable` which supports efficient element access using integer
|
||
indices via the :meth:`~object.__getitem__` special method and defines a
|
||
:meth:`~object.__len__` method that returns the length of the sequence.
|
||
Some built-in sequence types are :class:`list`, :class:`str`,
|
||
:class:`tuple`, and :class:`bytes`. Note that :class:`dict` also
|
||
supports :meth:`~object.__getitem__` and :meth:`!__len__`, but is considered a
|
||
mapping rather than a sequence because the lookups use arbitrary
|
||
:term:`immutable` keys rather than integers.
|
||
|
||
The :class:`collections.abc.Sequence` abstract base class
|
||
defines a much richer interface that goes beyond just
|
||
:meth:`~object.__getitem__` and :meth:`~object.__len__`, adding
|
||
:meth:`!count`, :meth:`!index`, :meth:`~object.__contains__`, and
|
||
:meth:`~object.__reversed__`. Types that implement this expanded
|
||
interface can be registered explicitly using
|
||
:func:`~abc.ABCMeta.register`. For more documentation on sequence
|
||
methods generally, see
|
||
:ref:`Common Sequence Operations <typesseq-common>`.
|
||
|
||
set comprehension
|
||
A compact way to process all or part of the elements in an iterable and
|
||
return a set with the results. ``results = {c for c in 'abracadabra' if
|
||
c not in 'abc'}`` generates the set of strings ``{'r', 'd'}``. See
|
||
:ref:`comprehensions`.
|
||
|
||
single dispatch
|
||
A form of :term:`generic function` dispatch where the implementation is
|
||
chosen based on the type of a single argument.
|
||
|
||
slice
|
||
An object usually containing a portion of a :term:`sequence`. A slice is
|
||
created using the subscript notation, ``[]`` with colons between numbers
|
||
when several are given, such as in ``variable_name[1:3:5]``. The bracket
|
||
(subscript) notation uses :class:`slice` objects internally.
|
||
|
||
soft deprecated
|
||
A soft deprecation can be used when using an API which should no longer
|
||
be used to write new code, but it remains safe to continue using it in
|
||
existing code. The API remains documented and tested, but will not be
|
||
developed further (no enhancement).
|
||
|
||
The main difference between a "soft" and a (regular) "hard" deprecation
|
||
is that the soft deprecation does not imply scheduling the removal of the
|
||
deprecated API.
|
||
|
||
Another difference is that a soft deprecation does not issue a warning.
|
||
|
||
See `PEP 387: Soft Deprecation
|
||
<https://peps.python.org/pep-0387/#soft-deprecation>`_.
|
||
|
||
special method
|
||
.. index:: pair: special; method
|
||
|
||
A method that is called implicitly by Python to execute a certain
|
||
operation on a type, such as addition. Such methods have names starting
|
||
and ending with double underscores. Special methods are documented in
|
||
:ref:`specialnames`.
|
||
|
||
statement
|
||
A statement is part of a suite (a "block" of code). A statement is either
|
||
an :term:`expression` or one of several constructs with a keyword, such
|
||
as :keyword:`if`, :keyword:`while` or :keyword:`for`.
|
||
|
||
static type checker
|
||
An external tool that reads Python code and analyzes it, looking for
|
||
issues such as incorrect types. See also :term:`type hints <type hint>`
|
||
and the :mod:`typing` module.
|
||
|
||
strong reference
|
||
In Python's C API, a strong reference is a reference to an object
|
||
which is owned by the code holding the reference. The strong
|
||
reference is taken by calling :c:func:`Py_INCREF` when the
|
||
reference is created and released with :c:func:`Py_DECREF`
|
||
when the reference is deleted.
|
||
|
||
The :c:func:`Py_NewRef` function can be used to create a strong reference
|
||
to an object. Usually, the :c:func:`Py_DECREF` function must be called on
|
||
the strong reference before exiting the scope of the strong reference, to
|
||
avoid leaking one reference.
|
||
|
||
See also :term:`borrowed reference`.
|
||
|
||
text encoding
|
||
A string in Python is a sequence of Unicode code points (in range
|
||
``U+0000``--``U+10FFFF``). To store or transfer a string, it needs to be
|
||
serialized as a sequence of bytes.
|
||
|
||
Serializing a string into a sequence of bytes is known as "encoding", and
|
||
recreating the string from the sequence of bytes is known as "decoding".
|
||
|
||
There are a variety of different text serialization
|
||
:ref:`codecs <standard-encodings>`, which are collectively referred to as
|
||
"text encodings".
|
||
|
||
text file
|
||
A :term:`file object` able to read and write :class:`str` objects.
|
||
Often, a text file actually accesses a byte-oriented datastream
|
||
and handles the :term:`text encoding` automatically.
|
||
Examples of text files are files opened in text mode (``'r'`` or ``'w'``),
|
||
:data:`sys.stdin`, :data:`sys.stdout`, and instances of
|
||
:class:`io.StringIO`.
|
||
|
||
See also :term:`binary file` for a file object able to read and write
|
||
:term:`bytes-like objects <bytes-like object>`.
|
||
|
||
triple-quoted string
|
||
A string which is bound by three instances of either a quotation mark
|
||
(") or an apostrophe ('). While they don't provide any functionality
|
||
not available with single-quoted strings, they are useful for a number
|
||
of reasons. They allow you to include unescaped single and double
|
||
quotes within a string and they can span multiple lines without the
|
||
use of the continuation character, making them especially useful when
|
||
writing docstrings.
|
||
|
||
type
|
||
The type of a Python object determines what kind of object it is; every
|
||
object has a type. An object's type is accessible as its
|
||
:attr:`~instance.__class__` attribute or can be retrieved with
|
||
``type(obj)``.
|
||
|
||
type alias
|
||
A synonym for a type, created by assigning the type to an identifier.
|
||
|
||
Type aliases are useful for simplifying :term:`type hints <type hint>`.
|
||
For example::
|
||
|
||
def remove_gray_shades(
|
||
colors: list[tuple[int, int, int]]) -> list[tuple[int, int, int]]:
|
||
pass
|
||
|
||
could be made more readable like this::
|
||
|
||
Color = tuple[int, int, int]
|
||
|
||
def remove_gray_shades(colors: list[Color]) -> list[Color]:
|
||
pass
|
||
|
||
See :mod:`typing` and :pep:`484`, which describe this functionality.
|
||
|
||
type hint
|
||
An :term:`annotation` that specifies the expected type for a variable, a class
|
||
attribute, or a function parameter or return value.
|
||
|
||
Type hints are optional and are not enforced by Python but
|
||
they are useful to :term:`static type checkers <static type checker>`.
|
||
They can also aid IDEs with code completion and refactoring.
|
||
|
||
Type hints of global variables, class attributes, and functions,
|
||
but not local variables, can be accessed using
|
||
:func:`typing.get_type_hints`.
|
||
|
||
See :mod:`typing` and :pep:`484`, which describe this functionality.
|
||
|
||
universal newlines
|
||
A manner of interpreting text streams in which all of the following are
|
||
recognized as ending a line: the Unix end-of-line convention ``'\n'``,
|
||
the Windows convention ``'\r\n'``, and the old Macintosh convention
|
||
``'\r'``. See :pep:`278` and :pep:`3116`, as well as
|
||
:func:`bytes.splitlines` for an additional use.
|
||
|
||
variable annotation
|
||
An :term:`annotation` of a variable or a class attribute.
|
||
|
||
When annotating a variable or a class attribute, assignment is optional::
|
||
|
||
class C:
|
||
field: 'annotation'
|
||
|
||
Variable annotations are usually used for
|
||
:term:`type hints <type hint>`: for example this variable is expected to take
|
||
:class:`int` values::
|
||
|
||
count: int = 0
|
||
|
||
Variable annotation syntax is explained in section :ref:`annassign`.
|
||
|
||
See :term:`function annotation`, :pep:`484`
|
||
and :pep:`526`, which describe this functionality.
|
||
Also see :ref:`annotations-howto`
|
||
for best practices on working with annotations.
|
||
|
||
virtual environment
|
||
A cooperatively isolated runtime environment that allows Python users
|
||
and applications to install and upgrade Python distribution packages
|
||
without interfering with the behaviour of other Python applications
|
||
running on the same system.
|
||
|
||
See also :mod:`venv`.
|
||
|
||
virtual machine
|
||
A computer defined entirely in software. Python's virtual machine
|
||
executes the :term:`bytecode` emitted by the bytecode compiler.
|
||
|
||
Zen of Python
|
||
Listing of Python design principles and philosophies that are helpful in
|
||
understanding and using the language. The listing can be found by typing
|
||
"``import this``" at the interactive prompt.
|