cpython/Doc/library/asyncio-eventloop.rst

.. currentmodule:: asyncio

.. _asyncio-event-loop:

Base Event Loop
===============

**Source code:** :source:`Lib/asyncio/events.py`

The event loop is the central execution device provided by :mod:`asyncio`.
It provides multiple facilities, including:

* Registering, executing and cancelling delayed calls (timeouts).

* Creating client and server :ref:`transports <asyncio-transport>` for various
  kinds of communication.

* Launching subprocesses and the associated :ref:`transports
  <asyncio-transport>` for communication with an external program.

* Delegating costly function calls to a pool of threads.

.. class:: BaseEventLoop

   This class is an implementation detail.  It is a subclass of
   :class:`AbstractEventLoop` and may be a base class of concrete
   event loop implementations found in :mod:`asyncio`.  It should not
   be used directly; use :class:`AbstractEventLoop` instead.
   ``BaseEventLoop`` should not be subclassed by third-party code; the
   internal interface is not stable.

.. class:: AbstractEventLoop

   Abstract base class of event loops.

   This class is :ref:`not thread safe <asyncio-multithreading>`.

Run an event loop
-----------------

.. method:: AbstractEventLoop.run_forever()

   Run until :meth:`stop` is called.  If :meth:`stop` is called before
   :meth:`run_forever()` is called, this polls the I/O selector once
   with a timeout of zero, runs all callbacks scheduled in response to
   I/O events (and those that were already scheduled), and then exits.
   If :meth:`stop` is called while :meth:`run_forever` is running,
   this will run the current batch of callbacks and then exit.  Note
   that callbacks scheduled by callbacks will not run in that case;
   they will run the next time :meth:`run_forever` is called.

   .. versionchanged:: 3.5.1

.. method:: AbstractEventLoop.run_until_complete(future)

   Run until the :class:`Future` is done.

   If the argument is a :ref:`coroutine object <coroutine>`, it is wrapped by
   :func:`ensure_future`.

   Return the Future's result, or raise its exception.

.. method:: AbstractEventLoop.is_running()

   Returns running status of event loop.

.. method:: AbstractEventLoop.stop()

   Stop running the event loop.

   This causes :meth:`run_forever` to exit at the next suitable
   opportunity (see there for more details).

   .. versionchanged:: 3.5.1

.. method:: AbstractEventLoop.is_closed()

   Returns ``True`` if the event loop was closed.

   .. versionadded:: 3.4.2

.. method:: AbstractEventLoop.close()

   Close the event loop. The loop must not be running.  Pending
   callbacks will be lost.

   This clears the queues and shuts down the executor, but does not wait for
   the executor to finish.

   This is idempotent and irreversible. No other methods should be called after
   this one.


.. coroutinemethod:: AbstractEventLoop.shutdown_asyncgens()

   Schedule all currently open :term:`asynchronous generator` objects to
   close with an :meth:`~agen.aclose()` call.  After calling this method,
   the event loop will issue a warning whenever a new asynchronous generator
   is iterated.  Should be used to finalize all scheduled asynchronous
   generators reliably.  Example::

    try:
        loop.run_forever()
    finally:
        loop.run_until_complete(loop.shutdown_asyncgens())
        loop.close()

   .. versionadded:: 3.6


.. _asyncio-pass-keywords:

Calls
-----

Most :mod:`asyncio` functions don't accept keywords. If you want to pass
keywords to your callback, use :func:`functools.partial`. For example,
``loop.call_soon(functools.partial(print, "Hello", flush=True))`` will call
``print("Hello", flush=True)``.

.. note::
   :func:`functools.partial` is better than ``lambda`` functions, because
   :mod:`asyncio` can inspect :func:`functools.partial` object to display
   parameters in debug mode, whereas ``lambda`` functions have a poor
   representation.

.. method:: AbstractEventLoop.call_soon(callback, \*args)

   Arrange for a callback to be called as soon as possible.  The callback is
   called after :meth:`call_soon` returns, when control returns to the event
   loop.

   This operates as a :abbr:`FIFO (first-in, first-out)` queue, callbacks
   are called in the order in which they are registered.  Each callback
   will be called exactly once.

   Any positional arguments after the callback will be passed to the
   callback when it is called.

   An instance of :class:`asyncio.Handle` is returned, which can be
   used to cancel the callback.

   :ref:`Use functools.partial to pass keywords to the callback
   <asyncio-pass-keywords>`.

.. method:: AbstractEventLoop.call_soon_threadsafe(callback, \*args)

   Like :meth:`call_soon`, but thread safe.

   See the :ref:`concurrency and multithreading <asyncio-multithreading>`
   section of the documentation.


.. _asyncio-delayed-calls:

Delayed calls
-------------

The event loop has its own internal clock for computing timeouts.
Which clock is used depends on the (platform-specific) event loop
implementation; ideally it is a monotonic clock.  This will generally be
a different clock than :func:`time.time`.

.. note::

   Timeouts (relative *delay* or absolute *when*) should not exceed one day.


.. method:: AbstractEventLoop.call_later(delay, callback, *args)

   Arrange for the *callback* to be called after the given *delay*
   seconds (either an int or float).

   An instance of :class:`asyncio.Handle` is returned, which can be
   used to cancel the callback.

   *callback* will be called exactly once per call to :meth:`call_later`.
   If two callbacks are scheduled for exactly the same time, it is
   undefined which will be called first.

   The optional positional *args* will be passed to the callback when it
   is called. If you want the callback to be called with some named
   arguments, use a closure or :func:`functools.partial`.

   :ref:`Use functools.partial to pass keywords to the callback
   <asyncio-pass-keywords>`.

.. method:: AbstractEventLoop.call_at(when, callback, *args)

   Arrange for the *callback* to be called at the given absolute timestamp
   *when* (an int or float), using the same time reference as
   :meth:`AbstractEventLoop.time`.

   This method's behavior is the same as :meth:`call_later`.

   An instance of :class:`asyncio.Handle` is returned, which can be
   used to cancel the callback.

   :ref:`Use functools.partial to pass keywords to the callback
   <asyncio-pass-keywords>`.

.. method:: AbstractEventLoop.time()

   Return the current time, as a :class:`float` value, according to the
   event loop's internal clock.

.. seealso::

   The :func:`asyncio.sleep` function.


Futures
-------

.. method:: AbstractEventLoop.create_future()

   Create an :class:`asyncio.Future` object attached to the loop.

   This is a preferred way to create futures in asyncio, as event
   loop implementations can provide alternative implementations
   of the Future class (with better performance or instrumentation).

   .. versionadded:: 3.5.2


Tasks
-----

.. method:: AbstractEventLoop.create_task(coro)

   Schedule the execution of a :ref:`coroutine object <coroutine>`: wrap it in
   a future. Return a :class:`Task` object.

   Third-party event loops can use their own subclass of :class:`Task` for
   interoperability. In this case, the result type is a subclass of
   :class:`Task`.

   This method was added in Python 3.4.2. Use the :func:`async` function to
   support also older Python versions.

   .. versionadded:: 3.4.2

.. method:: AbstractEventLoop.set_task_factory(factory)

   Set a task factory that will be used by
   :meth:`AbstractEventLoop.create_task`.

   If *factory* is ``None`` the default task factory will be set.

   If *factory* is a *callable*, it should have a signature matching
   ``(loop, coro)``, where *loop* will be a reference to the active
   event loop, *coro* will be a coroutine object.  The callable
   must return an :class:`asyncio.Future` compatible object.

   .. versionadded:: 3.4.4

.. method:: AbstractEventLoop.get_task_factory()

   Return a task factory, or ``None`` if the default one is in use.

   .. versionadded:: 3.4.4


Creating connections
--------------------

.. coroutinemethod:: AbstractEventLoop.create_connection(protocol_factory, host=None, port=None, \*, ssl=None, family=0, proto=0, flags=0, sock=None, local_addr=None, server_hostname=None)

   Create a streaming transport connection to a given Internet *host* and
   *port*: socket family :py:data:`~socket.AF_INET` or
   :py:data:`~socket.AF_INET6` depending on *host* (or *family* if specified),
   socket type :py:data:`~socket.SOCK_STREAM`.  *protocol_factory* must be a
   callable returning a :ref:`protocol <asyncio-protocol>` instance.

   This method is a :ref:`coroutine <coroutine>` which will try to
   establish the connection in the background.  When successful, the
   coroutine returns a ``(transport, protocol)`` pair.

   The chronological synopsis of the underlying operation is as follows:

   #. The connection is established, and a :ref:`transport <asyncio-transport>`
      is created to represent it.

   #. *protocol_factory* is called without arguments and must return a
      :ref:`protocol <asyncio-protocol>` instance.

   #. The protocol instance is tied to the transport, and its
      :meth:`connection_made` method is called.

   #. The coroutine returns successfully with the ``(transport, protocol)``
      pair.

   The created transport is an implementation-dependent bidirectional stream.

   .. note::
      *protocol_factory* can be any kind of callable, not necessarily
      a class.  For example, if you want to use a pre-created
      protocol instance, you can pass ``lambda: my_protocol``.

   Options that change how the connection is created:

   * *ssl*: if given and not false, a SSL/TLS transport is created
     (by default a plain TCP transport is created).  If *ssl* is
     a :class:`ssl.SSLContext` object, this context is used to create
     the transport; if *ssl* is :const:`True`, a context with some
     unspecified default settings is used.

     .. seealso:: :ref:`SSL/TLS security considerations <ssl-security>`

   * *server_hostname*, is only for use together with *ssl*,
     and sets or overrides the hostname that the target server's certificate
     will be matched against.  By default the value of the *host* argument
     is used.  If *host* is empty, there is no default and you must pass a
     value for *server_hostname*.  If *server_hostname* is an empty
     string, hostname matching is disabled (which is a serious security
     risk, allowing for man-in-the-middle-attacks).

   * *family*, *proto*, *flags* are the optional address family, protocol
     and flags to be passed through to getaddrinfo() for *host* resolution.
     If given, these should all be integers from the corresponding
     :mod:`socket` module constants.

   * *sock*, if given, should be an existing, already connected
     :class:`socket.socket` object to be used by the transport.
     If *sock* is given, none of *host*, *port*, *family*, *proto*, *flags*
     and *local_addr* should be specified.

   * *local_addr*, if given, is a ``(local_host, local_port)`` tuple used
     to bind the socket to locally.  The *local_host* and *local_port*
     are looked up using getaddrinfo(), similarly to *host* and *port*.

   .. versionchanged:: 3.5

      On Windows with :class:`ProactorEventLoop`, SSL/TLS is now supported.

   .. seealso::

      The :func:`open_connection` function can be used to get a pair of
      (:class:`StreamReader`, :class:`StreamWriter`) instead of a protocol.


.. coroutinemethod:: AbstractEventLoop.create_datagram_endpoint(protocol_factory, local_addr=None, remote_addr=None, \*, family=0, proto=0, flags=0, reuse_address=None, reuse_port=None, allow_broadcast=None, sock=None)

   Create datagram connection: socket family :py:data:`~socket.AF_INET` or
   :py:data:`~socket.AF_INET6` depending on *host* (or *family* if specified),
   socket type :py:data:`~socket.SOCK_DGRAM`. *protocol_factory* must be a
   callable returning a :ref:`protocol <asyncio-protocol>` instance.

   This method is a :ref:`coroutine <coroutine>` which will try to
   establish the connection in the background.  When successful, the
   coroutine returns a ``(transport, protocol)`` pair.

   Options changing how the connection is created:

   * *local_addr*, if given, is a ``(local_host, local_port)`` tuple used
     to bind the socket to locally.  The *local_host* and *local_port*
     are looked up using :meth:`getaddrinfo`.

   * *remote_addr*, if given, is a ``(remote_host, remote_port)`` tuple used
     to connect the socket to a remote address.  The *remote_host* and
     *remote_port* are looked up using :meth:`getaddrinfo`.

   * *family*, *proto*, *flags* are the optional address family, protocol
     and flags to be passed through to :meth:`getaddrinfo` for *host*
     resolution. If given, these should all be integers from the
     corresponding :mod:`socket` module constants.

   * *reuse_address* tells the kernel to reuse a local socket in
     TIME_WAIT state, without waiting for its natural timeout to
     expire. If not specified will automatically be set to ``True`` on
     UNIX.

   * *reuse_port* tells the kernel to allow this endpoint to be bound to the
     same port as other existing endpoints are bound to, so long as they all
     set this flag when being created. This option is not supported on Windows
     and some UNIX's. If the :py:data:`~socket.SO_REUSEPORT` constant is not
     defined then this capability is unsupported.

   * *allow_broadcast* tells the kernel to allow this endpoint to send
     messages to the broadcast address.

   * *sock* can optionally be specified in order to use a preexisting,
     already connected, :class:`socket.socket` object to be used by the
     transport. If specified, *local_addr* and *remote_addr* should be omitted
     (must be :const:`None`).

   On Windows with :class:`ProactorEventLoop`, this method is not supported.

   See :ref:`UDP echo client protocol <asyncio-udp-echo-client-protocol>` and
   :ref:`UDP echo server protocol <asyncio-udp-echo-server-protocol>` examples.


.. coroutinemethod:: AbstractEventLoop.create_unix_connection(protocol_factory, path, \*, ssl=None, sock=None, server_hostname=None)

   Create UNIX connection: socket family :py:data:`~socket.AF_UNIX`, socket
   type :py:data:`~socket.SOCK_STREAM`. The :py:data:`~socket.AF_UNIX` socket
   family is used to communicate between processes on the same machine
   efficiently.

   This method is a :ref:`coroutine <coroutine>` which will try to
   establish the connection in the background.  When successful, the
   coroutine returns a ``(transport, protocol)`` pair.

   *path* is the name of a UNIX domain socket, and is required unless a *sock*
   parameter is specified.  Abstract UNIX sockets, :class:`str`, and
   :class:`bytes` paths are supported.

   See the :meth:`AbstractEventLoop.create_connection` method for parameters.

   Availability: UNIX.


Creating listening connections
------------------------------

.. coroutinemethod:: AbstractEventLoop.create_server(protocol_factory, host=None, port=None, \*, family=socket.AF_UNSPEC, flags=socket.AI_PASSIVE, sock=None, backlog=100, ssl=None, reuse_address=None, reuse_port=None)

   Create a TCP server (socket type :data:`~socket.SOCK_STREAM`) bound to
   *host* and *port*.

   Return a :class:`Server` object, its :attr:`~Server.sockets` attribute
   contains created sockets. Use the :meth:`Server.close` method to stop the
   server: close listening sockets.

   Parameters:

   * The *host* parameter can be a string, in that case the TCP server is
     bound to *host* and *port*. The *host* parameter can also be a sequence
     of strings and in that case the TCP server is bound to all hosts of the
     sequence. If *host* is an empty string or ``None``, all interfaces are
     assumed and a list of multiple sockets will be returned (most likely one
     for IPv4 and another one for IPv6).

   * *family* can be set to either :data:`socket.AF_INET` or
     :data:`~socket.AF_INET6` to force the socket to use IPv4 or IPv6. If not set
     it will be determined from host (defaults to :data:`socket.AF_UNSPEC`).

   * *flags* is a bitmask for :meth:`getaddrinfo`.

   * *sock* can optionally be specified in order to use a preexisting
     socket object. If specified, *host* and *port* should be omitted (must be
     :const:`None`).

   * *backlog* is the maximum number of queued connections passed to
     :meth:`~socket.socket.listen` (defaults to 100).

   * *ssl* can be set to an :class:`~ssl.SSLContext` to enable SSL over the
     accepted connections.

   * *reuse_address* tells the kernel to reuse a local socket in
     TIME_WAIT state, without waiting for its natural timeout to
     expire. If not specified will automatically be set to ``True`` on
     UNIX.

   * *reuse_port* tells the kernel to allow this endpoint to be bound to the
     same port as other existing endpoints are bound to, so long as they all
     set this flag when being created. This option is not supported on
     Windows.

   This method is a :ref:`coroutine <coroutine>`.

   .. versionchanged:: 3.5

      On Windows with :class:`ProactorEventLoop`, SSL/TLS is now supported.

   .. seealso::

      The function :func:`start_server` creates a (:class:`StreamReader`,
      :class:`StreamWriter`) pair and calls back a function with this pair.

   .. versionchanged:: 3.5.1

      The *host* parameter can now be a sequence of strings.


.. coroutinemethod:: AbstractEventLoop.create_unix_server(protocol_factory, path=None, \*, sock=None, backlog=100, ssl=None)

   Similar to :meth:`AbstractEventLoop.create_server`, but specific to the
   socket family :py:data:`~socket.AF_UNIX`.

   This method is a :ref:`coroutine <coroutine>`.

   Availability: UNIX.

.. coroutinemethod:: BaseEventLoop.connect_accepted_socket(protocol_factory, sock, \*, ssl=None)

   Handle an accepted connection.

   This is used by servers that accept connections outside of
   asyncio but that use asyncio to handle them.

   Parameters:

   * *sock* is a preexisting socket object returned from an ``accept``
     call.

   * *ssl* can be set to an :class:`~ssl.SSLContext` to enable SSL over the
     accepted connections.

   This method is a :ref:`coroutine <coroutine>`.  When completed, the
   coroutine returns a ``(transport, protocol)`` pair.

Watch file descriptors
----------------------

On Windows with :class:`SelectorEventLoop`, only socket handles are supported
(ex: pipe file descriptors are not supported).

On Windows with :class:`ProactorEventLoop`, these methods are not supported.

.. method:: AbstractEventLoop.add_reader(fd, callback, \*args)

   Start watching the file descriptor for read availability and then call the
   *callback* with specified arguments.

   :ref:`Use functools.partial to pass keywords to the callback
   <asyncio-pass-keywords>`.

.. method:: AbstractEventLoop.remove_reader(fd)

   Stop watching the file descriptor for read availability.

.. method:: AbstractEventLoop.add_writer(fd, callback, \*args)

   Start watching the file descriptor for write availability and then call the
   *callback* with specified arguments.

   :ref:`Use functools.partial to pass keywords to the callback
   <asyncio-pass-keywords>`.

.. method:: AbstractEventLoop.remove_writer(fd)

   Stop watching the file descriptor for write availability.

The :ref:`watch a file descriptor for read events <asyncio-watch-read-event>`
example uses the low-level :meth:`AbstractEventLoop.add_reader` method to register
the file descriptor of a socket.


Low-level socket operations
---------------------------

.. coroutinemethod:: AbstractEventLoop.sock_recv(sock, nbytes)

   Receive data from the socket.  Modeled after blocking
   :meth:`socket.socket.recv` method.

   The return value is a bytes object
   representing the data received.  The maximum amount of data to be received
   at once is specified by *nbytes*.

   With :class:`SelectorEventLoop` event loop, the socket *sock* must be
   non-blocking.

   This method is a :ref:`coroutine <coroutine>`.

.. coroutinemethod:: AbstractEventLoop.sock_recv_into(sock, buf)

   Receive data from the socket.  Modeled after blocking
   :meth:`socket.socket.recv_into` method.

   The received data is written into *buf* (a writable buffer).
   The return value is the number of bytes written.

   With :class:`SelectorEventLoop` event loop, the socket *sock* must be
   non-blocking.

   This method is a :ref:`coroutine <coroutine>`.

   .. versionadded:: 3.7

.. coroutinemethod:: AbstractEventLoop.sock_sendall(sock, data)

   Send data to the socket.  Modeled after blocking
   :meth:`socket.socket.sendall` method.

   The socket must be connected to a remote socket.
   This method continues to send data from *data* until either all data has
   been sent or an error occurs.  ``None`` is returned on success.  On error,
   an exception is raised, and there is no way to determine how much data, if
   any, was successfully processed by the receiving end of the connection.

   With :class:`SelectorEventLoop` event loop, the socket *sock* must be
   non-blocking.

   This method is a :ref:`coroutine <coroutine>`.

.. coroutinemethod:: AbstractEventLoop.sock_connect(sock, address)

   Connect to a remote socket at *address*.  Modeled after
   blocking :meth:`socket.socket.connect` method.

   With :class:`SelectorEventLoop` event loop, the socket *sock* must be
   non-blocking.

   This method is a :ref:`coroutine <coroutine>`.

   .. versionchanged:: 3.5.2
      ``address`` no longer needs to be resolved.  ``sock_connect``
      will try to check if the *address* is already resolved by calling
      :func:`socket.inet_pton`.  If not,
      :meth:`AbstractEventLoop.getaddrinfo` will be used to resolve the
      *address*.

   .. seealso::

      :meth:`AbstractEventLoop.create_connection`
      and  :func:`asyncio.open_connection() <open_connection>`.


.. coroutinemethod:: AbstractEventLoop.sock_accept(sock)

   Accept a connection.  Modeled after blocking
   :meth:`socket.socket.accept`.

   The socket must be bound to an address and listening
   for connections. The return value is a pair ``(conn, address)`` where *conn*
   is a *new* socket object usable to send and receive data on the connection,
   and *address* is the address bound to the socket on the other end of the
   connection.

   The socket *sock* must be non-blocking.

   This method is a :ref:`coroutine <coroutine>`.

   .. seealso::

      :meth:`AbstractEventLoop.create_server` and :func:`start_server`.


Resolve host name
-----------------

.. coroutinemethod:: AbstractEventLoop.getaddrinfo(host, port, \*, family=0, type=0, proto=0, flags=0)

   This method is a :ref:`coroutine <coroutine>`, similar to
   :meth:`socket.getaddrinfo` function but non-blocking.

.. coroutinemethod:: AbstractEventLoop.getnameinfo(sockaddr, flags=0)

   This method is a :ref:`coroutine <coroutine>`, similar to
   :meth:`socket.getnameinfo` function but non-blocking.


Connect pipes
-------------

On Windows with :class:`SelectorEventLoop`, these methods are not supported.
Use :class:`ProactorEventLoop` to support pipes on Windows.

.. coroutinemethod:: AbstractEventLoop.connect_read_pipe(protocol_factory, pipe)

   Register read pipe in eventloop.

   *protocol_factory* should instantiate object with :class:`Protocol`
   interface.  *pipe* is a :term:`file-like object <file object>`.
   Return pair ``(transport, protocol)``, where *transport* supports the
   :class:`ReadTransport` interface.

   With :class:`SelectorEventLoop` event loop, the *pipe* is set to
   non-blocking mode.

   This method is a :ref:`coroutine <coroutine>`.

.. coroutinemethod:: AbstractEventLoop.connect_write_pipe(protocol_factory, pipe)

   Register write pipe in eventloop.

   *protocol_factory* should instantiate object with :class:`BaseProtocol`
   interface. *pipe* is :term:`file-like object <file object>`.
   Return pair ``(transport, protocol)``, where *transport* supports
   :class:`WriteTransport` interface.

   With :class:`SelectorEventLoop` event loop, the *pipe* is set to
   non-blocking mode.

   This method is a :ref:`coroutine <coroutine>`.

.. seealso::

   The :meth:`AbstractEventLoop.subprocess_exec` and
   :meth:`AbstractEventLoop.subprocess_shell` methods.


UNIX signals
------------

Availability: UNIX only.

.. method:: AbstractEventLoop.add_signal_handler(signum, callback, \*args)

   Add a handler for a signal.

   Raise :exc:`ValueError` if the signal number is invalid or uncatchable.
   Raise :exc:`RuntimeError` if there is a problem setting up the handler.

   :ref:`Use functools.partial to pass keywords to the callback
   <asyncio-pass-keywords>`.

.. method:: AbstractEventLoop.remove_signal_handler(sig)

   Remove a handler for a signal.

   Return ``True`` if a signal handler was removed, ``False`` if not.

.. seealso::

   The :mod:`signal` module.


Executor
--------

Call a function in an :class:`~concurrent.futures.Executor` (pool of threads or
pool of processes). By default, an event loop uses a thread pool executor
(:class:`~concurrent.futures.ThreadPoolExecutor`).

.. coroutinemethod:: AbstractEventLoop.run_in_executor(executor, func, \*args)

   Arrange for a *func* to be called in the specified executor.

   The *executor* argument should be an :class:`~concurrent.futures.Executor`
   instance. The default executor is used if *executor* is ``None``.

   :ref:`Use functools.partial to pass keywords to the *func*
   <asyncio-pass-keywords>`.

   This method is a :ref:`coroutine <coroutine>`.

   .. versionchanged:: 3.5.3
      :meth:`BaseEventLoop.run_in_executor` no longer configures the
      ``max_workers`` of the thread pool executor it creates, instead
      leaving it up to the thread pool executor
      (:class:`~concurrent.futures.ThreadPoolExecutor`) to set the
      default.

.. method:: AbstractEventLoop.set_default_executor(executor)

   Set the default executor used by :meth:`run_in_executor`.


Error Handling API
------------------

Allows customizing how exceptions are handled in the event loop.

.. method:: AbstractEventLoop.set_exception_handler(handler)

   Set *handler* as the new event loop exception handler.

   If *handler* is ``None``, the default exception handler will
   be set.

   If *handler* is a callable object, it should have a
   matching signature to ``(loop, context)``, where ``loop``
   will be a reference to the active event loop, ``context``
   will be a ``dict`` object (see :meth:`call_exception_handler`
   documentation for details about context).

.. method:: AbstractEventLoop.get_exception_handler()

   Return the exception handler, or ``None`` if the default one
   is in use.

   .. versionadded:: 3.5.2

.. method:: AbstractEventLoop.default_exception_handler(context)

   Default exception handler.

   This is called when an exception occurs and no exception
   handler is set, and can be called by a custom exception
   handler that wants to defer to the default behavior.

   *context* parameter has the same meaning as in
   :meth:`call_exception_handler`.

.. method:: AbstractEventLoop.call_exception_handler(context)

   Call the current event loop exception handler.

   *context* is a ``dict`` object containing the following keys
   (new keys may be introduced later):

   * 'message': Error message;
   * 'exception' (optional): Exception object;
   * 'future' (optional): :class:`asyncio.Future` instance;
   * 'handle' (optional): :class:`asyncio.Handle` instance;
   * 'protocol' (optional): :ref:`Protocol <asyncio-protocol>` instance;
   * 'transport' (optional): :ref:`Transport <asyncio-transport>` instance;
   * 'socket' (optional): :class:`socket.socket` instance.

   .. note::

       Note: this method should not be overloaded in subclassed
       event loops.  For any custom exception handling, use
       :meth:`set_exception_handler()` method.

Debug mode
----------

.. method:: AbstractEventLoop.get_debug()

   Get the debug mode (:class:`bool`) of the event loop.

   The default value is ``True`` if the environment variable
   :envvar:`PYTHONASYNCIODEBUG` is set to a non-empty string, ``False``
   otherwise.

   .. versionadded:: 3.4.2

.. method:: AbstractEventLoop.set_debug(enabled: bool)

   Set the debug mode of the event loop.

   .. versionadded:: 3.4.2

.. seealso::

   The :ref:`debug mode of asyncio <asyncio-debug-mode>`.

Server
------

.. class:: Server

   Server listening on sockets.

   Object created by the :meth:`AbstractEventLoop.create_server` method and the
   :func:`start_server` function. Don't instantiate the class directly.

   .. method:: close()

      Stop serving: close listening sockets and set the :attr:`sockets`
      attribute to ``None``.

      The sockets that represent existing incoming client connections are left
      open.

      The server is closed asynchronously, use the :meth:`wait_closed`
      coroutine to wait until the server is closed.

   .. coroutinemethod:: wait_closed()

      Wait until the :meth:`close` method completes.

      This method is a :ref:`coroutine <coroutine>`.

   .. attribute:: sockets

      List of :class:`socket.socket` objects the server is listening to, or
      ``None`` if the server is closed.


Handle
------

.. class:: Handle

   A callback wrapper object returned by :func:`AbstractEventLoop.call_soon`,
   :func:`AbstractEventLoop.call_soon_threadsafe`, :func:`AbstractEventLoop.call_later`,
   and :func:`AbstractEventLoop.call_at`.

   .. method:: cancel()

      Cancel the call.  If the callback is already canceled or executed,
      this method has no effect.


Event loop examples
-------------------

.. _asyncio-hello-world-callback:

Hello World with call_soon()
^^^^^^^^^^^^^^^^^^^^^^^^^^^^

Example using the :meth:`AbstractEventLoop.call_soon` method to schedule a
callback. The callback displays ``"Hello World"`` and then stops the event
loop::

    import asyncio

    def hello_world(loop):
        print('Hello World')
        loop.stop()

    loop = asyncio.get_event_loop()

    # Schedule a call to hello_world()
    loop.call_soon(hello_world, loop)

    # Blocking call interrupted by loop.stop()
    loop.run_forever()
    loop.close()

.. seealso::

   The :ref:`Hello World coroutine <asyncio-hello-world-coroutine>` example
   uses a :ref:`coroutine <coroutine>`.


.. _asyncio-date-callback:

Display the current date with call_later()
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

Example of callback displaying the current date every second. The callback uses
the :meth:`AbstractEventLoop.call_later` method to reschedule itself during 5
seconds, and then stops the event loop::

    import asyncio
    import datetime

    def display_date(end_time, loop):
        print(datetime.datetime.now())
        if (loop.time() + 1.0) < end_time:
            loop.call_later(1, display_date, end_time, loop)
        else:
            loop.stop()

    loop = asyncio.get_event_loop()

    # Schedule the first call to display_date()
    end_time = loop.time() + 5.0
    loop.call_soon(display_date, end_time, loop)

    # Blocking call interrupted by loop.stop()
    loop.run_forever()
    loop.close()

.. seealso::

   The :ref:`coroutine displaying the current date
   <asyncio-date-coroutine>` example uses a :ref:`coroutine
   <coroutine>`.


.. _asyncio-watch-read-event:

Watch a file descriptor for read events
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

Wait until a file descriptor received some data using the
:meth:`AbstractEventLoop.add_reader` method and then close the event loop::

    import asyncio
    try:
        from socket import socketpair
    except ImportError:
        from asyncio.windows_utils import socketpair

    # Create a pair of connected file descriptors
    rsock, wsock = socketpair()
    loop = asyncio.get_event_loop()

    def reader():
        data = rsock.recv(100)
        print("Received:", data.decode())
        # We are done: unregister the file descriptor
        loop.remove_reader(rsock)
        # Stop the event loop
        loop.stop()

    # Register the file descriptor for read event
    loop.add_reader(rsock, reader)

    # Simulate the reception of data from the network
    loop.call_soon(wsock.send, 'abc'.encode())

    # Run the event loop
    loop.run_forever()

    # We are done, close sockets and the event loop
    rsock.close()
    wsock.close()
    loop.close()

.. seealso::

   The :ref:`register an open socket to wait for data using a protocol
   <asyncio-register-socket>` example uses a low-level protocol created by the
   :meth:`AbstractEventLoop.create_connection` method.

   The :ref:`register an open socket to wait for data using streams
   <asyncio-register-socket-streams>` example uses high-level streams
   created by the :func:`open_connection` function in a coroutine.


Set signal handlers for SIGINT and SIGTERM
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

Register handlers for signals :py:data:`SIGINT` and :py:data:`SIGTERM` using
the :meth:`AbstractEventLoop.add_signal_handler` method::

    import asyncio
    import functools
    import os
    import signal

    def ask_exit(signame):
        print("got signal %s: exit" % signame)
        loop.stop()

    loop = asyncio.get_event_loop()
    for signame in ('SIGINT', 'SIGTERM'):
        loop.add_signal_handler(getattr(signal, signame),
                                functools.partial(ask_exit, signame))

    print("Event loop running forever, press Ctrl+C to interrupt.")
    print("pid %s: send SIGINT or SIGTERM to exit." % os.getpid())
    try:
        loop.run_forever()
    finally:
        loop.close()

This example only works on UNIX.