Doc/library/asyncio.rst - platform/external/python/cpython3 - Gitiles

 :mod:`asyncio` -- Asynchronous I/O, event loop, coroutines and tasks
 ====================================================================

 .. module:: asyncio
    :synopsis: Asynchronous I/O, event loop, coroutines and tasks.

 .. versionadded:: 3.4

 **Source code:** :source:`Lib/asyncio/`

 --------------

 This module provides infrastructure for writing single-threaded concurrent
 code using coroutines, multiplexing I/O access over sockets and other
 resources, running network clients and servers, and other related primitives.

 Here is a more detailed list of the package contents:

 * a pluggable :ref:`event loop <event-loop>` with various system-specific
   implementations;

 * :ref:`transport <transport>` and :ref:`protocol <protocol>` abstractions
   (similar to those in `Twisted <http://twistedmatrix.com/>`_);

 * concrete support for TCP, UDP, SSL, subprocess pipes, delayed calls, and
   others (some may be system-dependent);

 * a Future class that mimicks the one in the :mod:`concurrent.futures` module,
   but adapted for use with the event loop;

 * coroutines and tasks based on ``yield from`` (:PEP:`380`), to help write
   concurrent code in a sequential fashion;

 * cancellation support for Futures and coroutines;

 * :ref:`synchronization primitives <sync>` for use between coroutines in
   a single thread, mimicking those in the :mod:`threading` module;

 * an interface for passing work off to a threadpool, for times when
   you absolutely, positively have to use a library that makes blocking
   I/O calls.


 Disclaimer
 ----------

 Full documentation is not yet ready; we hope to have it written
 before Python 3.4 leaves beta.  Until then, the best reference is
 :PEP:`3156`.  For a motivational primer on transports and protocols,
 see :PEP:`3153`.


 .. XXX should the asyncio documentation come in several pages, as for logging?


 .. _event-loop:

 Event loops
 -----------

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

 * Registering, executing and cancelling delayed calls (timeouts)

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

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

 * Delegating costly function calls to a pool of threads

 Getting an event loop
 ^^^^^^^^^^^^^^^^^^^^^

 The easiest way to get an event loop is to call the :func:`get_event_loop`
 function.

 .. XXX more docs

 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`.

 .. method:: time()

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

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

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

    A "handle" is returned: an opaque object with a :meth:`cancel` method
    that can be used to cancel the call.

    *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`.

 .. method:: 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:`time`.

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

 Creating connections
 ^^^^^^^^^^^^^^^^^^^^

 .. method:: create_connection(protocol_factory, host=None, port=None, **options)

    Create a streaming transport connection to a given Internet *host* and
    *port*.  *protocol_factory* must be a callable returning a
    :ref:`protocol <protocol>` instance.

    This method returns 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 <transport>`
       is created to represent it.

    #. *protocol_factory* is called without arguments and must return a
       :ref:`protocol <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* are optional named arguments allowing to 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.

    * *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*.


 .. _protocol:

 Protocols
 ---------

 :mod:`asyncio` provides base classes that you can subclass to implement
 your network protocols.  Those classes are used in conjunction with
 :ref:`transports <transport>` (see below): the protocol parses incoming
 data and asks for the writing of outgoing data, while the transport is
 responsible for the actual I/O and buffering.

 When subclassing a protocol class, it is recommended you override certain
 methods.  Those methods are callbacks: they will be called by the transport
 on certain events (for example when some data is received); you shouldn't
 call them yourself, unless you are implementing a transport.

 .. note::
    All callbacks have default implementations, which are empty.  Therefore,
    you only need to implement the callbacks for the events in which you
    are interested.


 Protocol classes
 ^^^^^^^^^^^^^^^^

 .. class:: Protocol

    The base class for implementing streaming protocols (for use with
    e.g. TCP and SSL transports).

 .. class:: DatagramProtocol

    The base class for implementing datagram protocols (for use with
    e.g. UDP transports).

 .. class:: SubprocessProtocol

    The base class for implementing protocols communicating with child
    processes (through a set of unidirectional pipes).


 Connection callbacks
 ^^^^^^^^^^^^^^^^^^^^

 These callbacks may be called on :class:`Protocol` and
 :class:`SubprocessProtocol` instances:

 .. method:: connection_made(transport)

    Called when a connection is made.

    The *transport* argument is the transport representing the
    connection.  You are responsible for storing it somewhere
    (e.g. as an attribute) if you need to.

 .. method:: connection_lost(exc)

    Called when the connection is lost or closed.

    The argument is either an exception object or :const:`None`.
    The latter means a regular EOF is received, or the connection was
    aborted or closed by this side of the connection.

 :meth:`connection_made` and :meth:`connection_lost` are called exactly once
 per successful connection.  All other callbacks will be called between those
 two methods, which allows for easier resource management in your protocol
 implementation.

 The following callbacks may be called only on :class:`SubprocessProtocol`
 instances:

 .. method:: pipe_data_received(fd, data)

    Called when the child process writes data into its stdout or stderr pipe.
    *fd* is the integer file descriptor of the pipe.  *data* is a non-empty
    bytes object containing the data.

 .. method:: pipe_connection_lost(fd, exc)

    Called when one of the pipes communicating with the child process
    is closed.  *fd* is the integer file descriptor that was closed.

 .. method:: process_exited()

    Called when the child process has exited.


 Data reception callbacks
 ^^^^^^^^^^^^^^^^^^^^^^^^

 Streaming protocols
 """""""""""""""""""

 The following callbacks are called on :class:`Protocol` instances:

 .. method:: data_received(data)

    Called when some data is received.  *data* is a non-empty bytes object
    containing the incoming data.

    .. note::
       Whether the data is buffered, chunked or reassembled depends on
       the transport.  In general, you shouldn't rely on specific semantics
       and instead make your parsing generic and flexible enough.  However,
       data is always received in the correct order.

 .. method:: eof_received()

    Calls when the other end signals it won't send any more data
    (for example by calling :meth:`write_eof`, if the other end also uses
    asyncio).

    This method may return a false value (including None), in which case
    the transport will close itself.  Conversely, if this method returns a
    true value, closing the transport is up to the protocol.  Since the
    default implementation returns None, it implicitly closes the connection.

    .. note::
       Some transports such as SSL don't support half-closed connections,
       in which case returning true from this method will not prevent closing
       the connection.

 :meth:`data_received` can be called an arbitrary number of times during
 a connection.  However, :meth:`eof_received` is called at most once
 and, if called, :meth:`data_received` won't be called after it.

 Datagram protocols
 """"""""""""""""""

 The following callbacks are called on :class:`DatagramProtocol` instances.

 .. method:: datagram_received(data, addr)

    Called when a datagram is received.  *data* is a bytes object containing
    the incoming data.  *addr* is the address of the peer sending the data;
    the exact format depends on the transport.

 .. method:: error_received(exc)

    Called when a previous send or receive operation raises an
    :class:`OSError`.  *exc* is the :class:`OSError` instance.

    This method is called in rare conditions, when the transport (e.g. UDP)
    detects that a datagram couldn't be delivered to its recipient.
    In many conditions though, undeliverable datagrams will be silently
    dropped.


 Flow control callbacks
 ^^^^^^^^^^^^^^^^^^^^^^

 These callbacks may be called on :class:`Protocol` and
 :class:`SubprocessProtocol` instances:

 .. method:: pause_writing()

    Called when the transport's buffer goes over the high-water mark.

 .. method:: resume_writing()

    Called when the transport's buffer drains below the low-water mark.


 :meth:`pause_writing` and :meth:`resume_writing` calls are paired --
 :meth:`pause_writing` is called once when the buffer goes strictly over
 the high-water mark (even if subsequent writes increases the buffer size
 even more), and eventually :meth:`resume_writing` is called once when the
 buffer size reaches the low-water mark.

 .. note::
    If the buffer size equals the high-water mark,
    :meth:`pause_writing` is not called -- it must go strictly over.
    Conversely, :meth:`resume_writing` is called when the buffer size is
    equal or lower than the low-water mark.  These end conditions
    are important to ensure that things go as expected when either
    mark is zero.


 .. _transport:

 Transports
 ----------

 Transports are classed provided by :mod:`asyncio` in order to abstract
 various kinds of communication channels.  You generally won't instantiate
 a transport yourself; instead, you will call a :class:`EventLoop` method
 which will create the transport and try to initiate the underlying
 communication channel, calling you back when it succeeds.

 Once the communication channel is established, a transport is always
 paired with a :ref:`protocol <protocol>` instance.  The protocol can
 then call the transport's methods for various purposes.

 :mod:`asyncio` currently implements transports for TCP, UDP, SSL, and
 subprocess pipes.  The methods available on a transport depend on
 the transport's kind.

 Methods common to all transports
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 .. method:: close(self)

    Close the transport.  If the transport has a buffer for outgoing
    data, buffered data will be flushed asynchronously.  No more data
    will be received.  After all buffered data is flushed, the
    protocol's :meth:`connection_lost` method will be called with
    :const:`None` as its argument.


 .. method:: get_extra_info(name, default=None)

    Return optional transport information.  *name* is a string representing
    the piece of transport-specific information to get, *default* is the
    value to return if the information doesn't exist.

    This method allows transport implementations to easily expose
    channel-specific information.

 Methods of readable streaming transports
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 .. method:: pause_reading()

    Pause the receiving end of the transport.  No data will be passed to
    the protocol's :meth:`data_received` method until meth:`resume_reading`
    is called.

 .. method:: resume_reading()

    Resume the receiving end.  The protocol's :meth:`data_received` method
    will be called once again if some data is available for reading.

 Methods of writable streaming transports
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 .. method:: write(data)

    Write some *data* bytes to the transport.

    This method does not block; it buffers the data and arranges for it
    to be sent out asynchronously.

 .. method:: writelines(list_of_data)

    Write a list (or any iterable) of data bytes to the transport.
    This is functionally equivalent to calling :meth:`write` on each
    element yielded by the iterable, but may be implemented more efficiently.

 .. method:: write_eof()

    Close the write end of the transport after flushing buffered data.
    Data may still be received.

    This method can raise :exc:`NotImplementedError` if the transport
    (e.g. SSL) doesn't support half-closes.

 .. method:: can_write_eof()

    Return :const:`True` if the transport supports :meth:`write_eof`,
    :const:`False` if not.

 .. method:: abort()

    Close the transport immediately, without waiting for pending operations
    to complete.  Buffered data will be lost.  No more data will be received.
    The protocol's :meth:`connection_lost` method will eventually be
    called with :const:`None` as its argument.

 .. method:: set_write_buffer_limits(high=None, low=None)

    Set the *high*- and *low*-water limits for write flow control.

    These two values control when call the protocol's
    :meth:`pause_writing` and :meth:`resume_writing` methods are called.
    If specified, the low-water limit must be less than or equal to the
    high-water limit.  Neither *high* nor *low* can be negative.

    The defaults are implementation-specific.  If only the
    high-water limit is given, the low-water limit defaults to a
    implementation-specific value less than or equal to the
    high-water limit.  Setting *high* to zero forces *low* to zero as
    well, and causes :meth:`pause_writing` to be called whenever the
    buffer becomes non-empty.  Setting *low* to zero causes
    :meth:`resume_writing` to be called only once the buffer is empty.
    Use of zero for either limit is generally sub-optimal as it
    reduces opportunities for doing I/O and computation
    concurrently.

 .. method:: get_write_buffer_size()

    Return the current size of the output buffer used by the transport.

 Methods of datagram transports
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 .. method:: sendto(data, addr=None)

    Send the *data* bytes to the remote peer given by *addr* (a
    transport-dependent target address).  If *addr* is :const:`None`, the
    data is sent to the target address given on transport creation.

    This method does not block; it buffers the data and arranges for it
    to be sent out asynchronously.

 .. method:: abort()

    Close the transport immediately, without waiting for pending operations
    to complete.  Buffered data will be lost.  No more data will be received.
    The protocol's :meth:`connection_lost` method will eventually be
    called with :const:`None` as its argument.

 Methods of subprocess transports
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 .. method:: get_pid()

    Return the subprocess process id as an integer.

 .. method:: get_returncode()

    Return the subprocess returncode as an integer or :const:`None`
    if it hasn't returned, similarly to the
    :attr:`subprocess.Popen.returncode` attribute.

 .. method:: get_pipe_transport(fd)

    Return the transport for the communication pipe correspondong to the
    integer file descriptor *fd*.  The return value can be a readable or
    writable streaming transport, depending on the *fd*.  If *fd* doesn't
    correspond to a pipe belonging to this transport, :const:`None` is
    returned.

 .. method:: send_signal(signal)

    Send the *signal* number to the subprocess, as in
    :meth:`subprocess.Popen.send_signal`.

 .. method:: terminate()

    Ask the subprocess to stop, as in :meth:`subprocess.Popen.terminate`.
    This method is an alias for the :meth:`close` method.

    On POSIX systems, this method sends SIGTERM to the subprocess.
    On Windows, the Windows API function TerminateProcess() is called to
    stop the subprocess.

 .. method:: kill(self)

    Kill the subprocess, as in :meth:`subprocess.Popen.kill`

    On POSIX systems, the function sends SIGKILL to the subprocess.
    On Windows, this method is an alias for :meth:`terminate`.


 .. _coroutine:

 Coroutines
 ----------


 .. _sync:

 Synchronization primitives
 --------------------------


 Examples
 --------

 A :class:`Protocol` implementing an echo server::

    class EchoServer(asyncio.Protocol):

        TIMEOUT = 5.0

        def timeout(self):
            print('connection timeout, closing.')
            self.transport.close()

        def connection_made(self, transport):
            print('connection made')
            self.transport = transport

            # start 5 seconds timeout timer
            self.h_timeout = asyncio.get_event_loop().call_later(
                self.TIMEOUT, self.timeout)

        def data_received(self, data):
            print('data received: ', data.decode())
            self.transport.write(b'Re: ' + data)

            # restart timeout timer
            self.h_timeout.cancel()
            self.h_timeout = asyncio.get_event_loop().call_later(
                self.TIMEOUT, self.timeout)

        def eof_received(self):
            pass

        def connection_lost(self, exc):
            print('connection lost:', exc)
            self.h_timeout.cancel()
	:mod:`asyncio` -- Asynchronous I/O, event loop, coroutines and tasks
	====================================================================

	.. module:: asyncio
	:synopsis: Asynchronous I/O, event loop, coroutines and tasks.

	.. versionadded:: 3.4

	Source code: :source:`Lib/asyncio/`

	--------------

	This module provides infrastructure for writing single-threaded concurrent
	code using coroutines, multiplexing I/O access over sockets and other
	resources, running network clients and servers, and other related primitives.

	Here is a more detailed list of the package contents:

	* a pluggable :ref:`event loop <event-loop>` with various system-specific
	implementations;

	* :ref:`transport <transport>` and :ref:`protocol <protocol>` abstractions
	(similar to those in `Twisted <http://twistedmatrix.com/>`_);

	* concrete support for TCP, UDP, SSL, subprocess pipes, delayed calls, and
	others (some may be system-dependent);

	* a Future class that mimicks the one in the :mod:`concurrent.futures` module,
	but adapted for use with the event loop;

	* coroutines and tasks based on ``yield from`` (:PEP:`380`), to help write
	concurrent code in a sequential fashion;

	* cancellation support for Futures and coroutines;

	* :ref:`synchronization primitives <sync>` for use between coroutines in
	a single thread, mimicking those in the :mod:`threading` module;

	* an interface for passing work off to a threadpool, for times when
	you absolutely, positively have to use a library that makes blocking
	I/O calls.


	Disclaimer
	----------

	Full documentation is not yet ready; we hope to have it written
	before Python 3.4 leaves beta. Until then, the best reference is
	:PEP:`3156`. For a motivational primer on transports and protocols,
	see :PEP:`3153`.


	.. XXX should the asyncio documentation come in several pages, as for logging?


	.. _event-loop:

	Event loops
	-----------

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

	* Registering, executing and cancelling delayed calls (timeouts)

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

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

	* Delegating costly function calls to a pool of threads

	Getting an event loop
	^^^^^^^^^^^^^^^^^^^^^

	The easiest way to get an event loop is to call the :func:`get_event_loop`
	function.

	.. XXX more docs

	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`.

	.. method:: time()

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

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

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

	A "handle" is returned: an opaque object with a :meth:`cancel` method
	that can be used to cancel the call.

	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`.

	.. method:: 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:`time`.

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

	Creating connections
	^^^^^^^^^^^^^^^^^^^^

	.. method:: create_connection(protocol_factory, host=None, port=None, **options)

	Create a streaming transport connection to a given Internet host and
	port. protocol_factory must be a callable returning a
	:ref:`protocol <protocol>` instance.

	This method returns 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 <transport>`
	is created to represent it.

	#. protocol_factory is called without arguments and must return a
	:ref:`protocol <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 are optional named arguments allowing to 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.

	* 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.


	.. _protocol:

	Protocols
	---------

	:mod:`asyncio` provides base classes that you can subclass to implement
	your network protocols. Those classes are used in conjunction with
	:ref:`transports <transport>` (see below): the protocol parses incoming
	data and asks for the writing of outgoing data, while the transport is
	responsible for the actual I/O and buffering.

	When subclassing a protocol class, it is recommended you override certain
	methods. Those methods are callbacks: they will be called by the transport
	on certain events (for example when some data is received); you shouldn't
	call them yourself, unless you are implementing a transport.

	.. note::
	All callbacks have default implementations, which are empty. Therefore,
	you only need to implement the callbacks for the events in which you
	are interested.


	Protocol classes
	^^^^^^^^^^^^^^^^

	.. class:: Protocol

	The base class for implementing streaming protocols (for use with
	e.g. TCP and SSL transports).

	.. class:: DatagramProtocol

	The base class for implementing datagram protocols (for use with
	e.g. UDP transports).

	.. class:: SubprocessProtocol

	The base class for implementing protocols communicating with child
	processes (through a set of unidirectional pipes).


	Connection callbacks
	^^^^^^^^^^^^^^^^^^^^

	These callbacks may be called on :class:`Protocol` and
	:class:`SubprocessProtocol` instances:

	.. method:: connection_made(transport)

	Called when a connection is made.

	The transport argument is the transport representing the
	connection. You are responsible for storing it somewhere
	(e.g. as an attribute) if you need to.

	.. method:: connection_lost(exc)

	Called when the connection is lost or closed.

	The argument is either an exception object or :const:`None`.
	The latter means a regular EOF is received, or the connection was
	aborted or closed by this side of the connection.

	:meth:`connection_made` and :meth:`connection_lost` are called exactly once
	per successful connection. All other callbacks will be called between those
	two methods, which allows for easier resource management in your protocol
	implementation.

	The following callbacks may be called only on :class:`SubprocessProtocol`
	instances:

	.. method:: pipe_data_received(fd, data)

	Called when the child process writes data into its stdout or stderr pipe.
	fd is the integer file descriptor of the pipe. data is a non-empty
	bytes object containing the data.

	.. method:: pipe_connection_lost(fd, exc)

	Called when one of the pipes communicating with the child process
	is closed. fd is the integer file descriptor that was closed.

	.. method:: process_exited()

	Called when the child process has exited.


	Data reception callbacks
	^^^^^^^^^^^^^^^^^^^^^^^^

	Streaming protocols
	"""""""""""""""""""

	The following callbacks are called on :class:`Protocol` instances:

	.. method:: data_received(data)

	Called when some data is received. data is a non-empty bytes object
	containing the incoming data.

	.. note::
	Whether the data is buffered, chunked or reassembled depends on
	the transport. In general, you shouldn't rely on specific semantics
	and instead make your parsing generic and flexible enough. However,
	data is always received in the correct order.

	.. method:: eof_received()

	Calls when the other end signals it won't send any more data
	(for example by calling :meth:`write_eof`, if the other end also uses
	asyncio).

	This method may return a false value (including None), in which case
	the transport will close itself. Conversely, if this method returns a
	true value, closing the transport is up to the protocol. Since the
	default implementation returns None, it implicitly closes the connection.

	.. note::
	Some transports such as SSL don't support half-closed connections,
	in which case returning true from this method will not prevent closing
	the connection.

	:meth:`data_received` can be called an arbitrary number of times during
	a connection. However, :meth:`eof_received` is called at most once
	and, if called, :meth:`data_received` won't be called after it.

	Datagram protocols
	""""""""""""""""""

	The following callbacks are called on :class:`DatagramProtocol` instances.

	.. method:: datagram_received(data, addr)

	Called when a datagram is received. data is a bytes object containing
	the incoming data. addr is the address of the peer sending the data;
	the exact format depends on the transport.

	.. method:: error_received(exc)

	Called when a previous send or receive operation raises an
	:class:`OSError`. exc is the :class:`OSError` instance.

	This method is called in rare conditions, when the transport (e.g. UDP)
	detects that a datagram couldn't be delivered to its recipient.
	In many conditions though, undeliverable datagrams will be silently
	dropped.


	Flow control callbacks
	^^^^^^^^^^^^^^^^^^^^^^

	These callbacks may be called on :class:`Protocol` and
	:class:`SubprocessProtocol` instances:

	.. method:: pause_writing()

	Called when the transport's buffer goes over the high-water mark.

	.. method:: resume_writing()

	Called when the transport's buffer drains below the low-water mark.


	:meth:`pause_writing` and :meth:`resume_writing` calls are paired --
	:meth:`pause_writing` is called once when the buffer goes strictly over
	the high-water mark (even if subsequent writes increases the buffer size
	even more), and eventually :meth:`resume_writing` is called once when the
	buffer size reaches the low-water mark.

	.. note::
	If the buffer size equals the high-water mark,
	:meth:`pause_writing` is not called -- it must go strictly over.
	Conversely, :meth:`resume_writing` is called when the buffer size is
	equal or lower than the low-water mark. These end conditions
	are important to ensure that things go as expected when either
	mark is zero.


	.. _transport:

	Transports
	----------

	Transports are classed provided by :mod:`asyncio` in order to abstract
	various kinds of communication channels. You generally won't instantiate
	a transport yourself; instead, you will call a :class:`EventLoop` method
	which will create the transport and try to initiate the underlying
	communication channel, calling you back when it succeeds.

	Once the communication channel is established, a transport is always
	paired with a :ref:`protocol <protocol>` instance. The protocol can
	then call the transport's methods for various purposes.

	:mod:`asyncio` currently implements transports for TCP, UDP, SSL, and
	subprocess pipes. The methods available on a transport depend on
	the transport's kind.

	Methods common to all transports
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	.. method:: close(self)

	Close the transport. If the transport has a buffer for outgoing
	data, buffered data will be flushed asynchronously. No more data
	will be received. After all buffered data is flushed, the
	protocol's :meth:`connection_lost` method will be called with
	:const:`None` as its argument.


	.. method:: get_extra_info(name, default=None)

	Return optional transport information. name is a string representing
	the piece of transport-specific information to get, default is the
	value to return if the information doesn't exist.

	This method allows transport implementations to easily expose
	channel-specific information.

	Methods of readable streaming transports
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	.. method:: pause_reading()

	Pause the receiving end of the transport. No data will be passed to
	the protocol's :meth:`data_received` method until meth:`resume_reading`
	is called.

	.. method:: resume_reading()

	Resume the receiving end. The protocol's :meth:`data_received` method
	will be called once again if some data is available for reading.

	Methods of writable streaming transports
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	.. method:: write(data)

	Write some data bytes to the transport.

	This method does not block; it buffers the data and arranges for it
	to be sent out asynchronously.

	.. method:: writelines(list_of_data)

	Write a list (or any iterable) of data bytes to the transport.
	This is functionally equivalent to calling :meth:`write` on each
	element yielded by the iterable, but may be implemented more efficiently.

	.. method:: write_eof()

	Close the write end of the transport after flushing buffered data.
	Data may still be received.

	This method can raise :exc:`NotImplementedError` if the transport
	(e.g. SSL) doesn't support half-closes.

	.. method:: can_write_eof()

	Return :const:`True` if the transport supports :meth:`write_eof`,
	:const:`False` if not.

	.. method:: abort()

	Close the transport immediately, without waiting for pending operations
	to complete. Buffered data will be lost. No more data will be received.
	The protocol's :meth:`connection_lost` method will eventually be
	called with :const:`None` as its argument.

	.. method:: set_write_buffer_limits(high=None, low=None)

	Set the high- and low-water limits for write flow control.

	These two values control when call the protocol's
	:meth:`pause_writing` and :meth:`resume_writing` methods are called.
	If specified, the low-water limit must be less than or equal to the
	high-water limit. Neither high nor low can be negative.

	The defaults are implementation-specific. If only the
	high-water limit is given, the low-water limit defaults to a
	implementation-specific value less than or equal to the
	high-water limit. Setting high to zero forces low to zero as
	well, and causes :meth:`pause_writing` to be called whenever the
	buffer becomes non-empty. Setting low to zero causes
	:meth:`resume_writing` to be called only once the buffer is empty.
	Use of zero for either limit is generally sub-optimal as it
	reduces opportunities for doing I/O and computation
	concurrently.

	.. method:: get_write_buffer_size()

	Return the current size of the output buffer used by the transport.

	Methods of datagram transports
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	.. method:: sendto(data, addr=None)

	Send the data bytes to the remote peer given by addr (a
	transport-dependent target address). If addr is :const:`None`, the
	data is sent to the target address given on transport creation.

	This method does not block; it buffers the data and arranges for it
	to be sent out asynchronously.

	.. method:: abort()

	Close the transport immediately, without waiting for pending operations
	to complete. Buffered data will be lost. No more data will be received.
	The protocol's :meth:`connection_lost` method will eventually be
	called with :const:`None` as its argument.

	Methods of subprocess transports
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	.. method:: get_pid()

	Return the subprocess process id as an integer.

	.. method:: get_returncode()

	Return the subprocess returncode as an integer or :const:`None`
	if it hasn't returned, similarly to the
	:attr:`subprocess.Popen.returncode` attribute.

	.. method:: get_pipe_transport(fd)

	Return the transport for the communication pipe correspondong to the
	integer file descriptor fd. The return value can be a readable or
	writable streaming transport, depending on the fd. If fd doesn't
	correspond to a pipe belonging to this transport, :const:`None` is
	returned.

	.. method:: send_signal(signal)

	Send the signal number to the subprocess, as in
	:meth:`subprocess.Popen.send_signal`.

	.. method:: terminate()

	Ask the subprocess to stop, as in :meth:`subprocess.Popen.terminate`.
	This method is an alias for the :meth:`close` method.

	On POSIX systems, this method sends SIGTERM to the subprocess.
	On Windows, the Windows API function TerminateProcess() is called to
	stop the subprocess.

	.. method:: kill(self)

	Kill the subprocess, as in :meth:`subprocess.Popen.kill`

	On POSIX systems, the function sends SIGKILL to the subprocess.
	On Windows, this method is an alias for :meth:`terminate`.


	.. _coroutine:

	Coroutines
	----------


	.. _sync:

	Synchronization primitives
	--------------------------


	Examples
	--------

	A :class:`Protocol` implementing an echo server::

	class EchoServer(asyncio.Protocol):

	TIMEOUT = 5.0

	def timeout(self):
	print('connection timeout, closing.')
	self.transport.close()

	def connection_made(self, transport):
	print('connection made')
	self.transport = transport

	# start 5 seconds timeout timer
	self.h_timeout = asyncio.get_event_loop().call_later(
	self.TIMEOUT, self.timeout)

	def data_received(self, data):
	print('data received: ', data.decode())
	self.transport.write(b'Re: ' + data)

	# restart timeout timer
	self.h_timeout.cancel()
	self.h_timeout = asyncio.get_event_loop().call_later(
	self.TIMEOUT, self.timeout)

	def eof_received(self):
	pass

	def connection_lost(self, exc):
	print('connection lost:', exc)
	self.h_timeout.cancel()