mirror of https://github.com/python/cpython
369 lines
12 KiB
ReStructuredText
369 lines
12 KiB
ReStructuredText
:mod:`__main__` --- Top-level code environment
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==============================================
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.. module:: __main__
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:synopsis: The environment where top-level code is run. Covers command-line
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interfaces, import-time behavior, and ``__name__ == '__main__'``.
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--------------
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In Python, the special name ``__main__`` is used for two important constructs:
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1. the name of the top-level environment of the program, which can be
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checked using the ``__name__ == '__main__'`` expression; and
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2. the ``__main__.py`` file in Python packages.
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Both of these mechanisms are related to Python modules; how users interact with
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them and how they interact with each other. They are explained in detail
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below. If you're new to Python modules, see the tutorial section
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:ref:`tut-modules` for an introduction.
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.. _name_equals_main:
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``__name__ == '__main__'``
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---------------------------
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When a Python module or package is imported, ``__name__`` is set to the
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module's name. Usually, this is the name of the Python file itself without the
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``.py`` extension::
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>>> import configparser
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>>> configparser.__name__
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'configparser'
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If the file is part of a package, ``__name__`` will also include the parent
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package's path::
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>>> from concurrent.futures import process
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>>> process.__name__
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'concurrent.futures.process'
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However, if the module is executed in the top-level code environment,
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its ``__name__`` is set to the string ``'__main__'``.
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What is the "top-level code environment"?
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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``__main__`` is the name of the environment where top-level code is run.
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"Top-level code" is the first user-specified Python module that starts running.
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It's "top-level" because it imports all other modules that the program needs.
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Sometimes "top-level code" is called an *entry point* to the application.
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The top-level code environment can be:
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* the scope of an interactive prompt::
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>>> __name__
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'__main__'
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* the Python module passed to the Python interpreter as a file argument:
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.. code-block:: shell-session
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$ python helloworld.py
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Hello, world!
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* the Python module or package passed to the Python interpreter with the
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:option:`-m` argument:
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.. code-block:: shell-session
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$ python -m tarfile
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usage: tarfile.py [-h] [-v] (...)
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* Python code read by the Python interpreter from standard input:
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.. code-block:: shell-session
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$ echo "import this" | python
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The Zen of Python, by Tim Peters
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Beautiful is better than ugly.
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Explicit is better than implicit.
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...
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* Python code passed to the Python interpreter with the :option:`-c` argument:
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.. code-block:: shell-session
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$ python -c "import this"
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The Zen of Python, by Tim Peters
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Beautiful is better than ugly.
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Explicit is better than implicit.
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...
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In each of these situations, the top-level module's ``__name__`` is set to
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``'__main__'``.
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As a result, a module can discover whether or not it is running in the
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top-level environment by checking its own ``__name__``, which allows a common
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idiom for conditionally executing code when the module is not initialized from
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an import statement::
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if __name__ == '__main__':
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# Execute when the module is not initialized from an import statement.
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...
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.. seealso::
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For a more detailed look at how ``__name__`` is set in all situations, see
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the tutorial section :ref:`tut-modules`.
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Idiomatic Usage
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^^^^^^^^^^^^^^^
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Some modules contain code that is intended for script use only, like parsing
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command-line arguments or fetching data from standard input. If a module
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like this was imported from a different module, for example to unit test
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it, the script code would unintentionally execute as well.
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This is where using the ``if __name__ == '__main__'`` code block comes in
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handy. Code within this block won't run unless the module is executed in the
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top-level environment.
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Putting as few statements as possible in the block below ``if __name__ ==
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'__main__'`` can improve code clarity and correctness. Most often, a function
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named ``main`` encapsulates the program's primary behavior::
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# echo.py
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import shlex
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import sys
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def echo(phrase: str) -> None:
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"""A dummy wrapper around print."""
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# for demonstration purposes, you can imagine that there is some
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# valuable and reusable logic inside this function
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print(phrase)
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def main() -> int:
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"""Echo the input arguments to standard output"""
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phrase = shlex.join(sys.argv)
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echo(phrase)
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return 0
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if __name__ == '__main__':
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sys.exit(main()) # next section explains the use of sys.exit
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Note that if the module didn't encapsulate code inside the ``main`` function
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but instead put it directly within the ``if __name__ == '__main__'`` block,
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the ``phrase`` variable would be global to the entire module. This is
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error-prone as other functions within the module could be unintentionally using
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the global variable instead of a local name. A ``main`` function solves this
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problem.
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Using a ``main`` function has the added benefit of the ``echo`` function itself
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being isolated and importable elsewhere. When ``echo.py`` is imported, the
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``echo`` and ``main`` functions will be defined, but neither of them will be
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called, because ``__name__ != '__main__'``.
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Packaging Considerations
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^^^^^^^^^^^^^^^^^^^^^^^^
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``main`` functions are often used to create command-line tools by specifying
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them as entry points for console scripts. When this is done,
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`pip <https://pip.pypa.io/>`_ inserts the function call into a template script,
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where the return value of ``main`` is passed into :func:`sys.exit`.
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For example::
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sys.exit(main())
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Since the call to ``main`` is wrapped in :func:`sys.exit`, the expectation is
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that your function will return some value acceptable as an input to
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:func:`sys.exit`; typically, an integer or ``None`` (which is implicitly
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returned if your function does not have a return statement).
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By proactively following this convention ourselves, our module will have the
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same behavior when run directly (i.e. ``python echo.py``) as it will have if
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we later package it as a console script entry-point in a pip-installable
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package.
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In particular, be careful about returning strings from your ``main`` function.
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:func:`sys.exit` will interpret a string argument as a failure message, so
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your program will have an exit code of ``1``, indicating failure, and the
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string will be written to :data:`sys.stderr`. The ``echo.py`` example from
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earlier exemplifies using the ``sys.exit(main())`` convention.
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.. seealso::
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`Python Packaging User Guide <https://packaging.python.org/>`_
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contains a collection of tutorials and references on how to distribute and
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install Python packages with modern tools.
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``__main__.py`` in Python Packages
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----------------------------------
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If you are not familiar with Python packages, see section :ref:`tut-packages`
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of the tutorial. Most commonly, the ``__main__.py`` file is used to provide
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a command-line interface for a package. Consider the following hypothetical
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package, "bandclass":
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.. code-block:: text
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bandclass
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├── __init__.py
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├── __main__.py
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└── student.py
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``__main__.py`` will be executed when the package itself is invoked
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directly from the command line using the :option:`-m` flag. For example:
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.. code-block:: shell-session
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$ python -m bandclass
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This command will cause ``__main__.py`` to run. How you utilize this mechanism
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will depend on the nature of the package you are writing, but in this
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hypothetical case, it might make sense to allow the teacher to search for
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students::
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# bandclass/__main__.py
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import sys
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from .student import search_students
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student_name = sys.argv[2] if len(sys.argv) >= 2 else ''
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print(f'Found student: {search_students(student_name)}')
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Note that ``from .student import search_students`` is an example of a relative
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import. This import style can be used when referencing modules within a
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package. For more details, see :ref:`intra-package-references` in the
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:ref:`tut-modules` section of the tutorial.
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Idiomatic Usage
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^^^^^^^^^^^^^^^
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The contents of ``__main__.py`` typically isn't fenced with
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``if __name__ == '__main__'`` blocks. Instead, those files are kept short,
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functions to execute from other modules. Those other modules can then be
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easily unit-tested and are properly reusable.
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If used, an ``if __name__ == '__main__'`` block will still work as expected
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for a ``__main__.py`` file within a package, because its ``__name__``
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attribute will include the package's path if imported::
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>>> import asyncio.__main__
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>>> asyncio.__main__.__name__
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'asyncio.__main__'
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This won't work for ``__main__.py`` files in the root directory of a .zip file
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though. Hence, for consistency, minimal ``__main__.py`` like the :mod:`venv`
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one mentioned below are preferred.
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.. seealso::
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See :mod:`venv` for an example of a package with a minimal ``__main__.py``
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in the standard library. It doesn't contain a ``if __name__ == '__main__'``
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block. You can invoke it with ``python -m venv [directory]``.
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See :mod:`runpy` for more details on the :option:`-m` flag to the
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interpreter executable.
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See :mod:`zipapp` for how to run applications packaged as *.zip* files. In
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this case Python looks for a ``__main__.py`` file in the root directory of
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the archive.
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``import __main__``
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-------------------
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Regardless of which module a Python program was started with, other modules
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running within that same program can import the top-level environment's scope
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(:term:`namespace`) by importing the ``__main__`` module. This doesn't import
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a ``__main__.py`` file but rather whichever module that received the special
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name ``'__main__'``.
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Here is an example module that consumes the ``__main__`` namespace::
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# namely.py
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import __main__
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def did_user_define_their_name():
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return 'my_name' in dir(__main__)
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def print_user_name():
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if not did_user_define_their_name():
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raise ValueError('Define the variable `my_name`!')
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if '__file__' in dir(__main__):
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print(__main__.my_name, "found in file", __main__.__file__)
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else:
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print(__main__.my_name)
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Example usage of this module could be as follows::
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# start.py
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import sys
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from namely import print_user_name
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# my_name = "Dinsdale"
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def main():
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try:
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print_user_name()
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except ValueError as ve:
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return str(ve)
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if __name__ == "__main__":
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sys.exit(main())
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Now, if we started our program, the result would look like this:
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.. code-block:: shell-session
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$ python start.py
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Define the variable `my_name`!
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The exit code of the program would be 1, indicating an error. Uncommenting the
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line with ``my_name = "Dinsdale"`` fixes the program and now it exits with
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status code 0, indicating success:
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.. code-block:: shell-session
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$ python start.py
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Dinsdale found in file /path/to/start.py
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Note that importing ``__main__`` doesn't cause any issues with unintentionally
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running top-level code meant for script use which is put in the
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``if __name__ == "__main__"`` block of the ``start`` module. Why does this work?
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Python inserts an empty ``__main__`` module in :data:`sys.modules` at
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interpreter startup, and populates it by running top-level code. In our example
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this is the ``start`` module which runs line by line and imports ``namely``.
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In turn, ``namely`` imports ``__main__`` (which is really ``start``). That's an
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import cycle! Fortunately, since the partially populated ``__main__``
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module is present in :data:`sys.modules`, Python passes that to ``namely``.
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See :ref:`Special considerations for __main__ <import-dunder-main>` in the
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import system's reference for details on how this works.
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The Python REPL is another example of a "top-level environment", so anything
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defined in the REPL becomes part of the ``__main__`` scope::
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>>> import namely
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>>> namely.did_user_define_their_name()
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False
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>>> namely.print_user_name()
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Traceback (most recent call last):
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...
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ValueError: Define the variable `my_name`!
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>>> my_name = 'Jabberwocky'
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>>> namely.did_user_define_their_name()
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True
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>>> namely.print_user_name()
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Jabberwocky
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Note that in this case the ``__main__`` scope doesn't contain a ``__file__``
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attribute as it's interactive.
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The ``__main__`` scope is used in the implementation of :mod:`pdb` and
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:mod:`rlcompleter`.
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