mirror of https://github.com/python/cpython
540 lines
20 KiB
ReStructuredText
540 lines
20 KiB
ReStructuredText
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:mod:`socketserver` --- A framework for network servers
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=======================================================
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.. module:: socketserver
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:synopsis: A framework for network servers.
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The :mod:`socketserver` module simplifies the task of writing network servers.
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There are four basic server classes: :class:`TCPServer` uses the Internet TCP
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protocol, which provides for continuous streams of data between the client and
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server. :class:`UDPServer` uses datagrams, which are discrete packets of
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information that may arrive out of order or be lost while in transit. The more
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infrequently used :class:`UnixStreamServer` and :class:`UnixDatagramServer`
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classes are similar, but use Unix domain sockets; they're not available on
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non-Unix platforms. For more details on network programming, consult a book
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such as
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W. Richard Steven's UNIX Network Programming or Ralph Davis's Win32 Network
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Programming.
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These four classes process requests :dfn:`synchronously`; each request must be
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completed before the next request can be started. This isn't suitable if each
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request takes a long time to complete, because it requires a lot of computation,
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or because it returns a lot of data which the client is slow to process. The
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solution is to create a separate process or thread to handle each request; the
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:class:`ForkingMixIn` and :class:`ThreadingMixIn` mix-in classes can be used to
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support asynchronous behaviour.
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Creating a server requires several steps. First, you must create a request
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handler class by subclassing the :class:`BaseRequestHandler` class and
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overriding its :meth:`handle` method; this method will process incoming
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requests. Second, you must instantiate one of the server classes, passing it
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the server's address and the request handler class. Finally, call the
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:meth:`handle_request` or :meth:`serve_forever` method of the server object to
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process one or many requests.
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When inheriting from :class:`ThreadingMixIn` for threaded connection behavior,
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you should explicitly declare how you want your threads to behave on an abrupt
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shutdown. The :class:`ThreadingMixIn` class defines an attribute
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*daemon_threads*, which indicates whether or not the server should wait for
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thread termination. You should set the flag explicitly if you would like threads
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to behave autonomously; the default is :const:`False`, meaning that Python will
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not exit until all threads created by :class:`ThreadingMixIn` have exited.
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Server classes have the same external methods and attributes, no matter what
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network protocol they use.
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Server Creation Notes
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---------------------
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There are five classes in an inheritance diagram, four of which represent
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synchronous servers of four types::
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+------------+
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| BaseServer |
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+------------+
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v
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+-----------+ +------------------+
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| TCPServer |------->| UnixStreamServer |
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+-----------+ +------------------+
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v
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+-----------+ +--------------------+
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| UDPServer |------->| UnixDatagramServer |
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+-----------+ +--------------------+
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Note that :class:`UnixDatagramServer` derives from :class:`UDPServer`, not from
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:class:`UnixStreamServer` --- the only difference between an IP and a Unix
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stream server is the address family, which is simply repeated in both Unix
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server classes.
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Forking and threading versions of each type of server can be created using the
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:class:`ForkingMixIn` and :class:`ThreadingMixIn` mix-in classes. For instance,
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a threading UDP server class is created as follows::
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class ThreadingUDPServer(ThreadingMixIn, UDPServer): pass
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The mix-in class must come first, since it overrides a method defined in
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:class:`UDPServer`. Setting the various member variables also changes the
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behavior of the underlying server mechanism.
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To implement a service, you must derive a class from :class:`BaseRequestHandler`
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and redefine its :meth:`handle` method. You can then run various versions of
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the service by combining one of the server classes with your request handler
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class. The request handler class must be different for datagram or stream
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services. This can be hidden by using the handler subclasses
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:class:`StreamRequestHandler` or :class:`DatagramRequestHandler`.
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Of course, you still have to use your head! For instance, it makes no sense to
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use a forking server if the service contains state in memory that can be
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modified by different requests, since the modifications in the child process
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would never reach the initial state kept in the parent process and passed to
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each child. In this case, you can use a threading server, but you will probably
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have to use locks to protect the integrity of the shared data.
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On the other hand, if you are building an HTTP server where all data is stored
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externally (for instance, in the file system), a synchronous class will
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essentially render the service "deaf" while one request is being handled --
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which may be for a very long time if a client is slow to receive all the data it
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has requested. Here a threading or forking server is appropriate.
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In some cases, it may be appropriate to process part of a request synchronously,
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but to finish processing in a forked child depending on the request data. This
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can be implemented by using a synchronous server and doing an explicit fork in
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the request handler class :meth:`handle` method.
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Another approach to handling multiple simultaneous requests in an environment
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that supports neither threads nor :func:`fork` (or where these are too expensive
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or inappropriate for the service) is to maintain an explicit table of partially
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finished requests and to use :func:`select` to decide which request to work on
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next (or whether to handle a new incoming request). This is particularly
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important for stream services where each client can potentially be connected for
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a long time (if threads or subprocesses cannot be used). See :mod:`asyncore` for
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another way to manage this.
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.. XXX should data and methods be intermingled, or separate?
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how should the distinction between class and instance variables be drawn?
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Server Objects
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--------------
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.. class:: BaseServer
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This is the superclass of all Server objects in the module. It defines the
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interface, given below, but does not implement most of the methods, which is
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done in subclasses.
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.. method:: BaseServer.fileno()
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Return an integer file descriptor for the socket on which the server is
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listening. This function is most commonly passed to :func:`select.select`, to
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allow monitoring multiple servers in the same process.
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.. method:: BaseServer.handle_request()
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Process a single request. This function calls the following methods in
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order: :meth:`get_request`, :meth:`verify_request`, and
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:meth:`process_request`. If the user-provided :meth:`handle` method of the
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handler class raises an exception, the server's :meth:`handle_error` method
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will be called. If no request is received within :attr:`self.timeout`
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seconds, :meth:`handle_timeout` will be called and :meth:`handle_request`
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will return.
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.. method:: BaseServer.serve_forever(poll_interval=0.5)
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Handle requests until an explicit :meth:`shutdown` request. Polls for
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shutdown every *poll_interval* seconds.
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.. method:: BaseServer.shutdown()
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Tells the :meth:`serve_forever` loop to stop and waits until it does.
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.. attribute:: BaseServer.address_family
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The family of protocols to which the server's socket belongs.
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Common examples are :const:`socket.AF_INET` and :const:`socket.AF_UNIX`.
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.. attribute:: BaseServer.RequestHandlerClass
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The user-provided request handler class; an instance of this class is created
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for each request.
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.. attribute:: BaseServer.server_address
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The address on which the server is listening. The format of addresses varies
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depending on the protocol family; see the documentation for the socket module
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for details. For Internet protocols, this is a tuple containing a string giving
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the address, and an integer port number: ``('127.0.0.1', 80)``, for example.
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.. attribute:: BaseServer.socket
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The socket object on which the server will listen for incoming requests.
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The server classes support the following class variables:
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.. XXX should class variables be covered before instance variables, or vice versa?
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.. attribute:: BaseServer.allow_reuse_address
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Whether the server will allow the reuse of an address. This defaults to
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:const:`False`, and can be set in subclasses to change the policy.
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.. attribute:: BaseServer.request_queue_size
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The size of the request queue. If it takes a long time to process a single
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request, any requests that arrive while the server is busy are placed into a
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queue, up to :attr:`request_queue_size` requests. Once the queue is full,
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further requests from clients will get a "Connection denied" error. The default
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value is usually 5, but this can be overridden by subclasses.
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.. attribute:: BaseServer.socket_type
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The type of socket used by the server; :const:`socket.SOCK_STREAM` and
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:const:`socket.SOCK_DGRAM` are two common values.
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.. attribute:: BaseServer.timeout
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Timeout duration, measured in seconds, or :const:`None` if no timeout is
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desired. If :meth:`handle_request` receives no incoming requests within the
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timeout period, the :meth:`handle_timeout` method is called.
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There are various server methods that can be overridden by subclasses of base
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server classes like :class:`TCPServer`; these methods aren't useful to external
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users of the server object.
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.. XXX should the default implementations of these be documented, or should
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it be assumed that the user will look at socketserver.py?
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.. method:: BaseServer.finish_request()
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Actually processes the request by instantiating :attr:`RequestHandlerClass` and
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calling its :meth:`handle` method.
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.. method:: BaseServer.get_request()
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Must accept a request from the socket, and return a 2-tuple containing the *new*
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socket object to be used to communicate with the client, and the client's
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address.
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.. method:: BaseServer.handle_error(request, client_address)
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This function is called if the :attr:`RequestHandlerClass`'s :meth:`handle`
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method raises an exception. The default action is to print the traceback to
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standard output and continue handling further requests.
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.. method:: BaseServer.handle_timeout()
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This function is called when the :attr:`timeout` attribute has been set to a
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value other than :const:`None` and the timeout period has passed with no
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requests being received. The default action for forking servers is
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to collect the status of any child processes that have exited, while
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in threading servers this method does nothing.
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.. method:: BaseServer.process_request(request, client_address)
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Calls :meth:`finish_request` to create an instance of the
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:attr:`RequestHandlerClass`. If desired, this function can create a new process
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or thread to handle the request; the :class:`ForkingMixIn` and
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:class:`ThreadingMixIn` classes do this.
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.. Is there any point in documenting the following two functions?
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What would the purpose of overriding them be: initializing server
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instance variables, adding new network families?
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.. method:: BaseServer.server_activate()
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Called by the server's constructor to activate the server. The default behavior
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just :meth:`listen`\ s to the server's socket. May be overridden.
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.. method:: BaseServer.server_bind()
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Called by the server's constructor to bind the socket to the desired address.
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May be overridden.
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.. method:: BaseServer.verify_request(request, client_address)
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Must return a Boolean value; if the value is :const:`True`, the request will be
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processed, and if it's :const:`False`, the request will be denied. This function
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can be overridden to implement access controls for a server. The default
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implementation always returns :const:`True`.
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RequestHandler Objects
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----------------------
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The request handler class must define a new :meth:`handle` method, and can
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override any of the following methods. A new instance is created for each
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request.
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.. method:: RequestHandler.finish()
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Called after the :meth:`handle` method to perform any clean-up actions
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required. The default implementation does nothing. If :meth:`setup` or
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:meth:`handle` raise an exception, this function will not be called.
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.. method:: RequestHandler.handle()
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This function must do all the work required to service a request. The
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default implementation does nothing. Several instance attributes are
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available to it; the request is available as :attr:`self.request`; the client
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address as :attr:`self.client_address`; and the server instance as
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:attr:`self.server`, in case it needs access to per-server information.
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The type of :attr:`self.request` is different for datagram or stream
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services. For stream services, :attr:`self.request` is a socket object; for
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datagram services, :attr:`self.request` is a pair of string and socket.
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However, this can be hidden by using the request handler subclasses
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:class:`StreamRequestHandler` or :class:`DatagramRequestHandler`, which
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override the :meth:`setup` and :meth:`finish` methods, and provide
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:attr:`self.rfile` and :attr:`self.wfile` attributes. :attr:`self.rfile` and
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:attr:`self.wfile` can be read or written, respectively, to get the request
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data or return data to the client.
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.. method:: RequestHandler.setup()
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Called before the :meth:`handle` method to perform any initialization actions
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required. The default implementation does nothing.
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Examples
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--------
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:class:`socketserver.TCPServer` Example
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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This is the server side::
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import socketserver
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class MyTCPHandler(socketserver.BaseRequestHandler):
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"""
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The RequestHandler class for our server.
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It is instantiated once per connection to the server, and must
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override the handle() method to implement communication to the
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client.
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"""
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def handle(self):
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# self.request is the TCP socket connected to the client
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self.data = self.request.recv(1024).strip()
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print("%s wrote:" % self.client_address[0])
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print(self.data)
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# just send back the same data, but upper-cased
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self.request.send(self.data.upper())
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if __name__ == "__main__":
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HOST, PORT = "localhost", 9999
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# Create the server, binding to localhost on port 9999
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server = socketserver.TCPServer((HOST, PORT), MyTCPHandler)
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# Activate the server; this will keep running until you
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# interrupt the program with Ctrl-C
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server.serve_forever()
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An alternative request handler class that makes use of streams (file-like
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objects that simplify communication by providing the standard file interface)::
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class MyTCPHandler(socketserver.StreamRequestHandler):
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def handle(self):
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# self.rfile is a file-like object created by the handler;
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# we can now use e.g. readline() instead of raw recv() calls
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self.data = self.rfile.readline().strip()
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print("%s wrote:" % self.client_address[0])
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print(self.data)
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# Likewise, self.wfile is a file-like object used to write back
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# to the client
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self.wfile.write(self.data.upper())
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The difference is that the ``readline()`` call in the second handler will call
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``recv()`` multiple times until it encounters a newline character, while the
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single ``recv()`` call in the first handler will just return what has been sent
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from the client in one ``send()`` call.
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This is the client side::
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import socket
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import sys
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HOST, PORT = "localhost", 9999
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data = " ".join(sys.argv[1:])
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# Create a socket (SOCK_STREAM means a TCP socket)
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sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
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# Connect to server and send data
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sock.connect((HOST, PORT))
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sock.send(bytes(data + "\n","utf8"))
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# Receive data from the server and shut down
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received = sock.recv(1024)
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sock.close()
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print("Sent: %s" % data)
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print("Received: %s" % received)
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The output of the example should look something like this:
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Server::
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$ python TCPServer.py
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127.0.0.1 wrote:
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b'hello world with TCP'
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127.0.0.1 wrote:
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b'python is nice'
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Client::
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$ python TCPClient.py hello world with TCP
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Sent: hello world with TCP
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Received: b'HELLO WORLD WITH TCP'
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$ python TCPClient.py python is nice
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Sent: python is nice
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Received: b'PYTHON IS NICE'
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:class:`socketserver.UDPServer` Example
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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This is the server side::
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import socketserver
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class MyUDPHandler(socketserver.BaseRequestHandler):
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"""
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This class works similar to the TCP handler class, except that
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self.request consists of a pair of data and client socket, and since
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there is no connection the client address must be given explicitly
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when sending data back via sendto().
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"""
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def handle(self):
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data = self.request[0].strip()
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socket = self.request[1]
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print("%s wrote:" % self.client_address[0])
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print(data)
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socket.sendto(data.upper(), self.client_address)
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if __name__ == "__main__":
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HOST, PORT = "localhost", 9999
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server = socketserver.UDPServer((HOST, PORT), MyUDPHandler)
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server.serve_forever()
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This is the client side::
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import socket
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import sys
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HOST, PORT = "localhost", 9999
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data = " ".join(sys.argv[1:])
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# SOCK_DGRAM is the socket type to use for UDP sockets
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sock = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
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# As you can see, there is no connect() call; UDP has no connections.
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# Instead, data is directly sent to the recipient via sendto().
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sock.sendto(bytes(data + "\n","utf8"), (HOST, PORT))
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received = sock.recv(1024)
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print("Sent: %s" % data)
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print("Received: %s" % received)
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The output of the example should look exactly like for the TCP server example.
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Asynchronous Mixins
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~~~~~~~~~~~~~~~~~~~
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To build asynchronous handlers, use the :class:`ThreadingMixIn` and
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:class:`ForkingMixIn` classes.
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An example for the :class:`ThreadingMixIn` class::
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import socket
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import threading
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import socketserver
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class ThreadedTCPRequestHandler(socketserver.BaseRequestHandler):
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def handle(self):
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data = self.request.recv(1024)
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cur_thread = threading.current_thread()
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response = bytes("%s: %s" % (cur_thread.getName(), data),'ascii')
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self.request.send(response)
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class ThreadedTCPServer(socketserver.ThreadingMixIn, socketserver.TCPServer):
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pass
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def client(ip, port, message):
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sock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
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sock.connect((ip, port))
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sock.send(message)
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response = sock.recv(1024)
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print("Received: %s" % response)
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sock.close()
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if __name__ == "__main__":
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# Port 0 means to select an arbitrary unused port
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HOST, PORT = "localhost", 0
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server = ThreadedTCPServer((HOST, PORT), ThreadedTCPRequestHandler)
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ip, port = server.server_address
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# Start a thread with the server -- that thread will then start one
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# more thread for each request
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server_thread = threading.Thread(target=server.serve_forever)
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# Exit the server thread when the main thread terminates
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server_thread.setDaemon(True)
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server_thread.start()
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print("Server loop running in thread:", server_thread.name)
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client(ip, port, b"Hello World 1")
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client(ip, port, b"Hello World 2")
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client(ip, port, b"Hello World 3")
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server.shutdown()
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The output of the example should look something like this::
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$ python ThreadedTCPServer.py
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Server loop running in thread: Thread-1
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Received: b"Thread-2: b'Hello World 1'"
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Received: b"Thread-3: b'Hello World 2'"
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Received: b"Thread-4: b'Hello World 3'"
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The :class:`ForkingMixIn` class is used in the same way, except that the server
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will spawn a new process for each request.
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