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864 lines
35 KiB
ReStructuredText
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.. _howitworks:
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How Mitogen Works
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=================
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Some effort is required to accomplish the seemingly magical feat of
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bootstrapping a remote Python process without any software installed on the
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remote machine. The steps involved are unlikely to be immediately obvious to
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the casual reader, and they required several iterations to discover, so we
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document them thoroughly below.
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The UNIX First Stage
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--------------------
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To allow delivery of the bootstrap compressed using :py:mod:`zlib`, it is
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necessary for something on the remote to be prepared to decompress the payload
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and feed it to a Python interpreter. Since we would like to avoid writing an
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error-prone shell fragment to implement this, and since we must avoid writing
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to the remote machine's disk in case it is read-only, the Python process
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started on the remote machine by Mitogen immediately forks in order to
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implement the decompression.
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Python Command Line
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###################
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The Python command line sent to the host is a :mod:`zlib`-compressed [#f1]_ and
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base64-encoded copy of the :py:meth:`mitogen.master.Stream._first_stage`
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function, which has been carefully optimized to reduce its size. Prior to
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compression and encoding, ``CONTEXT_NAME`` is replaced with the desired context
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name in the function's source code.
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.. code::
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python -c 'exec "xxx".decode("base64").decode("zlib")'
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The command-line arranges for the Python interpreter to decode the base64'd
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component, decompress it and execute it as Python code. Base64 is used since
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to protect against any special characters that may be interpreted by the system
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shell in use.
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Forking The First Stage
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#######################
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The first stage creates a UNIX pipe and saves a copy of the process's real
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``stdin`` file descriptor (used for communication with the master) so that it
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can be recovered by the bootstrapped process later. It then forks into a new
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process.
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After fork, the parent half overwrites its ``stdin`` with the read end of the
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pipe, and the child half writes the string ``EC0\n``, then begins reading the
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:py:mod:`zlib`-compressed payload supplied on ``stdin`` by the master, and
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writing the decompressed result to the write-end of the UNIX pipe.
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To allow recovery of ``stdin`` for reuse by the bootstrapped process for
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parent<->child communication, it is necessary for the first stage to avoid
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closing ``stdin`` or reading from it until until EOF. Therefore, the master
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sends the :py:mod:`zlib`-compressed payload prefixed with an integer size,
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allowing reading by the first stage of exactly the required bytes.
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Configuring argv[0]
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###################
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Forking provides us with an excellent opportunity for tidying up the eventual
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Python interpreter, in particular, restarting it using a fresh command-line to
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get rid of the large base64-encoded first stage parameter, and to replace
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**argv[0]** with something descriptive.
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After configuring its ``stdin`` to point to the read end of the pipe, the
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parent half of the fork re-executes Python, with **argv[0]** taken from the
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``CONTEXT_NAME`` variable earlier substituted into its source code. As no
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arguments are provided to this new execution of Python, and since ``stdin`` is
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connected to a pipe (whose write end is connected to the first stage), the
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Python interpreter begins reading source code to execute from the pipe
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connected to ``stdin``.
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Bootstrap Preparation
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#####################
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Now we have the mechanism in place to send a :py:mod:`zlib`-compressed script
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to the remote Python interpreter, it is time to choose what to send.
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The script sent is simply the source code for :py:mod:`mitogen.core`, with a
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single line suffixed to trigger execution of the
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:py:meth:`mitogen.core.ExternalContext.main` function. The encoded arguments
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to the main function include some additional details, such as the logging package
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level that was active in the parent process, and whether debugging or profiling
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are enabled.
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After the script source code is prepared, it is passed through
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:py:func:`mitogen.master.minimize_source` to strip it of docstrings and
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comments, while preserving line numbers. This reduces the compressed payload
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by around 20%.
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Preserving The `mitogen.core` Source
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####################################
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One final trick is implemented in the first stage: after bootstrapping the new
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child, it writes a duplicate copy of the :py:mod:`mitogen.core` source it just
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used to bootstrap it back into another pipe connected to the child. The child's
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module importer cache is initialized with a copy of the source, so that
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subsequent bootstraps of children-of-children do not require the source to be
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fetched from the master a second time.
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Signalling Success
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##################
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Once the first stage has signalled ``EC0\n``, the master knows it is ready to
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receive the compressed bootstrap. After decompressing and writing the bootstrap
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source to its parent Python interpreter, the first stage writes the string
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``EC1\n`` to ``stdout`` before exiting. The master process waits for this
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string before considering bootstrap successful and the child's ``stdio`` ready
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to receive messages.
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ExternalContext.main()
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----------------------
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.. automethod:: mitogen.core.ExternalContext.main
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Generating A Synthetic `mitogen` Package
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########################################
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Since the bootstrap consists of the :py:mod:`mitogen.core` source code, and
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this code is loaded by Python by way of its main script (:mod:`__main__`
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module), initially the module layout in the child will be incorrect.
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The first step taken after bootstrap is to rearrange :py:data:`sys.modules` slightly
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so that :py:mod:`mitogen.core` appears in the correct location, and all
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classes defined in that module have their ``__module__`` attribute fixed up
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such that :py:mod:`cPickle` correctly serializes instance module names.
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Once a synthetic :py:mod:`mitogen` package and :py:mod:`mitogen.core` module
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have been generated, the bootstrap **deletes** `sys.modules['__main__']`, so
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that any attempt to import it (by :py:mod:`cPickle`) will cause the import to
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be satisfied by fetching the master's actual :mod:`__main__` module. This is
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necessary to allow master programs to be written as a self-contained Python
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script.
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Reaping The First Stage
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#######################
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After the bootstrap has called :py:func:`os.dup` on the copy of the ``stdin``
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file descriptor saved by the first stage, it is closed.
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Additionally, since the first stage was forked prior to re-executing the Python
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interpreter, it will exist as a zombie process until the parent process reaps
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it. Therefore the bootstrap must call :py:func:`os.wait` soon after startup.
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Setup Logging
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#############
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The child's :py:mod:`logging` package root logger is configured to have the
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same log level as the root logger in the master, and
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:py:class:`mitogen.core.LogHandler` is installed to forward logs to the master
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context's :py:data:`FORWARD_LOG <mitogen.core.FORWARD_LOG>` handle.
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The log level is copied into the child to avoid generating a potentially large
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amount of network IO forwarding logs that will simply be filtered away once
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they reach the master.
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The Module Importer
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###################
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An instance of :py:class:`mitogen.core.Importer` is installed in
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:py:data:`sys.meta_path`, where Python's :keyword:`import` statement will
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execute it before attempting to find a module locally.
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Standard IO Redirection
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#######################
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Two instances of :py:class:`mitogen.core.IoLogger` are created, one for
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``stdout`` and one for ``stderr``. This class creates a UNIX pipe whose read
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end is added to the IO multiplexer, and whose write end is used to overwrite
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the handles inherited during process creation.
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Even without IO redirection, something must replace ``stdin`` and ``stdout``,
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otherwise it is possible for the stream used for communication between parent
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and child to be accidentally corrupted by subprocesses run by user code.
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The inherited ``stdin`` is replaced by a file descriptor pointing to
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``/dev/null``.
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Finally Python's :py:data:`sys.stdout` is reopened to ensure line buffering is
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active, so that ``print`` statements and suchlike promptly appear in the logs.
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Function Call Dispatch
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######################
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.. currentmodule:: mitogen.core
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After all initialization is complete, the child's main thread sits in a loop
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reading from a :py:class:`Channel <mitogen.core.Channel>` connected to the
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:py:data:`CALL_FUNCTION <mitogen.core.CALL_FUNCTION>` handle. This handle is
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written to by
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:py:meth:`call() <mitogen.master.Context.call>`
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and :py:meth:`call_async() <mitogen.master.Context.call_async>`.
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:py:data:`CALL_FUNCTION <mitogen.core.CALL_FUNCTION>` only accepts requests
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from the context IDs listed in :py:data:`mitogen.parent_ids`, forming a chain
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of trust between the master and any intermediate context leading to the
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recipient of the message. In combination with :ref:`source-verification`, this
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is a major contributor to ensuring contexts running on compromised
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infrastructure cannot trigger code execution in siblings or any parent.
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Shutdown
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########
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.. currentmodule:: mitogen.core
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When a context receives :py:data:`SHUTDOWN <mitogen.core.SHUTDOWN>` from its
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immediate parent, it closes its own :py:data:`CALL_FUNCTION
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<mitogen.core.CALL_FUNCTION>` :py:class:`Channel <mitogen.core.Channel>` before
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sending :py:data:`SHUTDOWN <mitogen.core.SHUTDOWN>` to any directly connected
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children. Closing the channel has the effect of causing
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:py:meth:`ExternalContext._dispatch_calls` to exit and begin joining on the
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broker thread.
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During shutdown, the master waits up to 5 seconds for children to disconnect
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gracefully before force disconnecting them, while children will use that time
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to call :py:meth:`socket.shutdown(SHUT_WR) <socket.socket.shutdown>` on their
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:py:class:`IoLogger <mitogen.core.IoLogger>` socket's write ends before
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draining any remaining data buffered on the read ends, and ensuring any
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deferred broker function callbacks have had a chance to complete, necessary to
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capture for example forwarding any remaining :py:mod:`logging` records.
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An alternative approach is to wait until the IoLogger socket is completely
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closed, with some hard timeout, but this necessitates greater discipline than
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is common in infrastructure code (how often have you forgotten to redirect
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stderr to ``/dev/null`` when starting a daemon process?), so needless
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irritating delays would often be experienced during program termination.
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If the main thread (responsible for function call dispatch) fails to shut down
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gracefully, because some user function is hanging, it will still be cleaned up
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since as the final step in broker shutdown, the broker sends
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:py:mod:`signal.SIGTERM <signal>` to its own process.
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.. _stream-protocol:
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Stream Protocol
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---------------
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.. currentmodule:: mitogen.core
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Once connected, a basic framing protocol is used to communicate between
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parent and child:
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.. list-table::
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:header-rows: 1
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:widths: auto
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* - Field
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- Size
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- Description
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* - `dst_id`
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- 2
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- Integer target context ID. :py:class:`Router` delivers messages
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locally when their `dst_id` matches :py:data:`mitogen.context_id`,
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otherwise they are routed up or downstream.
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* - `src_id`
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- 2
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- Integer source context ID. Used as the target of replies if any are
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generated.
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* - `auth_id`
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- 2
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- The context ID under whose authority the message is acting. See
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:py:ref:`source-verification`.
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* - `handle`
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- 4
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- Integer target handle in the destination context. This is one of the
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:py:ref:`standard-handles`, or a dynamically generated handle used to
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receive a one-time reply, such as the return value of a function call.
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* - `reply_to`
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- 4
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- Integer target handle to direct any reply to this message. Used to
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receive a one-time reply, such as the return value of a function call.
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* - `length`
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- 4
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- Length of the data part of the message.
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* - `data`
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- n/a
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- Message data, which may be raw or pickled.
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.. _standard-handles:
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Standard Handles
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################
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Masters listen on the following handles:
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.. _FORWARD_LOG:
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.. currentmodule:: mitogen.core
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.. data:: FORWARD_LOG
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Receives `(logger_name, level, msg)` 3-tuples and writes them to the
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master's ``mitogen.ctx.<context_name>`` logger.
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.. _GET_MODULE:
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.. currentmodule:: mitogen.core
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.. data:: GET_MODULE
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Receives the name of a module to load `fullname`, locates the source code
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for `fullname`, and routes one or more :py:data:`LOAD_MODULE` messages back
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towards the sender of the :py:data:`GET_MODULE` request. If lookup fails,
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``None`` is sent instead.
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See :ref:`import-preloading` for a deeper discussion of
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:py:data:`GET_MODULE`/:py:data:`LOAD_MODULE`.
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.. _ALLOCATE_ID:
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.. currentmodule:: mitogen.core
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.. data:: ALLOCATE_ID
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Replies to any message sent to it with a newly allocated unique context ID,
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to allow children to safely start their own contexts. In future this is
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likely to be replaced by 32-bit context IDs and pseudorandom allocation,
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with an improved :py:data:`ADD_ROUTE` message sent upstream rather than
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downstream that generates NACKs if any ancestor detects an ID collision.
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Children listen on the following handles:
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.. _LOAD_MODULE:
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.. currentmodule:: mitogen.core
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.. data:: LOAD_MODULE
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Receives `(pkg_present, path, compressed, related)` tuples, composed of:
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* **pkg_present**: Either ``None`` for a plain ``.py`` module, or a list of
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canonical names of submodules existing witin this package. For example, a
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:py:data:`LOAD_MODULE` for the :py:mod:`mitogen` package would return a
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list like: `["mitogen.core", "mitogen.fakessh", "mitogen.master", ..]`.
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This list is used by children to avoid generating useless round-trips due
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to Python 2.x's :keyword:`import` statement behavior.
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* **path**: Original filesystem where the module was found on the master.
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* **compressed**: :py:mod:`zlib`-compressed module source code.
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* **related**: list of canonical module names on which this module appears
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to depend. Used by children that have ever started any children of their
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own to preload those children with :py:data:`LOAD_MODULE` messages in
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response to a :py:data:`GET_MODULE` request.
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.. _CALL_FUNCTION:
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.. currentmodule:: mitogen.core
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.. data:: CALL_FUNCTION
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Receives `(mod_name, class_name, func_name, args, kwargs)`
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5-tuples from
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:py:meth:`call_async() <mitogen.master.Context.call_async>`,
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imports ``mod_name``, then attempts to execute
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`class_name.func_name(\*args, \**kwargs)`.
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When this channel is closed (by way of sending :py:data:`_DEAD` to it), the
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child's main thread begins graceful shutdown of its own :py:class:`Broker`
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and :py:class:`Router`.
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.. _SHUTDOWN:
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.. currentmodule:: mitogen.core
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.. data:: SHUTDOWN
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When received from a child's immediate parent, causes the broker thread to
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enter graceful shutdown, including writing :py:data:`_DEAD` to the child's
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main thread, causing it to join on the exit of the broker thread.
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The final step of a child's broker shutdown process sends
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:py:mod:`signal.SIGTERM <signal>` to itself, ensuring the process dies even
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if the main thread was hung executing user code.
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Each context is responsible for sending :py:data:`SHUTDOWN` to each of its
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directly connected children in response to the master sending
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:py:data:`SHUTDOWN` to it, and arranging for the connection to its parent
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to be closed shortly thereafter.
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.. _ADD_ROUTE:
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.. currentmodule:: mitogen.core
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.. data:: ADD_ROUTE
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Receives `(target_id, via_id)` integer tuples, describing how messages
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arriving at this context on any stream should be forwarded on the stream
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associated with the context `via_id` such that they are eventually
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delivered to the target context.
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This message is necessary to inform intermediary contexts of the existence
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of a downstream Context, as they do not otherwise parse traffic they are
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fowarding to their downstream contexts that may cause new contexts to be
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established.
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Given a chain `master -> ssh1 -> sudo1`, no :py:data:`ADD_ROUTE` message is
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necessary, since :py:class:`mitogen.core.Router` in the `ssh` context can
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arrange to update its routes while setting up the new child during
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:py:meth:`Router.proxy_connect() <mitogen.master.Router.proxy_connect>`.
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However, given a chain like `master -> ssh1 -> sudo1 -> ssh2 -> sudo2`,
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`ssh1` requires an :py:data:`ADD_ROUTE` for `ssh2`, and both `ssh1` and
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`sudo1` require an :py:data:`ADD_ROUTE` for `sudo2`, as neither directly
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dealt with its establishment.
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Children that have ever been used to create a descendent child also listen on
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the following handles:
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.. currentmodule:: mitogen.core
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.. data:: GET_MODULE
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As with master's ``GET_MODULE``, except this implementation
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(:py:class:`mitogen.master.ModuleForwarder`) serves responses using
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:py:class:`mitogen.core.Importer`'s cache before forwarding the request to
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its parent context. The response is cached by each context in turn before
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being forwarded on to the child context that originally made the request.
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In this way, the master need never re-send a module it has already sent to
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a direct descendant.
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Additional handles are created to receive the result of every function call
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triggered by :py:meth:`call_async() <mitogen.master.Context.call_async>`.
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Sentinel Value
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##############
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.. _DEAD:
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.. currentmodule:: mitogen.core
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.. data:: _DEAD
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This special value is used to signal disconnection or closure of the remote
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end. It is used internally by :py:class:`Channel <mitogen.core.Channel>`
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and also passed to any function still registered with
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:py:meth:`add_handler() <mitogen.core.Router.add_handler>` during Broker
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shutdown.
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Use of Pickle
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#############
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The current implementation uses the Python :py:mod:`cPickle` module, with a
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restrictive class whitelist to prevent triggering undesirable code execution.
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The primary reason for using :py:mod:`cPickle` is that it is computationally
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efficient, and avoids including a potentially large body of serialization code
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in the bootstrap.
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The pickler will instantiate only built-in types and one of 3 constructor
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functions, to support unpickling :py:class:`CallError
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<mitogen.core.CallError>`, :py:data:`_DEAD <mitogen.core._DEAD>`, and
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:py:class:`Context <mitogen.core.Context>`.
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The choice of Pickle is one area to be revisited later. All accounts suggest it
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cannot be used securely, however few of those accounts appear to be expert, and
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none mention any additional attacks that would not be prevented by using a
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restrictive class whitelist.
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The IO Multiplexer
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------------------
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Since we must include our IO multiplexer as part of the bootstrap,
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off-the-shelf implementations are for the most part entirely inappropriate. For
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example, a minimal copy of Twisted weighs in at around 440KiB and is composed
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of approximately 115 files. Even if we could arrange for an entire Python
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package to be transferred during bootstrap, this minimal configuration is
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massive in comparison to Mitogen's solution, multiplies quickly in the
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presence of many machines, and would require manually splitting up the parts of
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Twisted that we would like to use.
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.. _routing:
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Message Routing
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---------------
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Routing assumes it is impossible to construct a tree such that one of a
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context's parents will not know the ID of a target the context is attempting to
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communicate with.
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When :py:class:`mitogen.core.Router` receives a message, it checks the IDs
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associated with its directly connected streams for a potential route. If any
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stream matches, either because it directly connects to the target ID, or
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because the master sent an :py:data:`ADD_ROUTE <mitogen.core.ADD_ROUTE>`
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message associating it, then the message will be forwarded down the tree using
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that stream.
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If the message does not match any :py:data:`ADD_ROUTE <mitogen.core.ADD_ROUTE>`
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message or stream, instead it is forwarded upwards to the immediate parent, and
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recursively by each parent in turn until one is reached that knows how to
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forward the message down the tree.
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When the master establishes a new context via an existing child context, it
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sends corresponding :py:data:`ADD_ROUTE <mitogen.core.ADD_ROUTE>` messages to
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each indirect parent between the context and the root.
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Example
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#######
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.. image:: images/context-tree.png
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In the diagram, when ``master`` is creating the ``sudo:node12b:webapp``
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context, it must send ``ADD_ROUTE`` messages to ``rack12``, ``dc1``,
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``bastion``, and itself; ``node12b`` does not require an ``ADD_ROUTE`` message
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since it has a stream directly connected to the new context.
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When ``sudo:node22a:webapp`` wants to send a message to
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``sudo:node12b:webapp``, the message will be routed as follows:
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``sudo:node22a:webapp -> node22a -> rack22 -> dc2 -> bastion -> dc1 -> rack12 -> node12b -> sudo:node12b:webapp``
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.. image:: images/route.png
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.. _source-verification:
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Source Verification
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###################
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Before forwarding or dispatching a message it has received,
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:py:class:`mitogen.core.Router` first looks up the corresponding
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:py:class:`mitogen.core.Stream` it would use to send responses towards the
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context ID listed in the `auth_id` field, and if the looked up stream does not
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match the stream on which the message was received, the message is discarded
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and a warning is logged.
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This creates a trust chain leading up to the root of the tree, preventing
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downstream contexts from injecting messages appearing to be from the master or
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any more trustworthy parent. In this way, privileged functionality such as
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:py:data:`CALL_FUNCTION <mitogen.core.CALL_FUNCTION>` can base trust decisions
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on the accuracy of :py:ref:`auth_id <stream-protocol>`.
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The `auth_id` field is separate from `src_id` in order to support granting
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privilege to contexts that do not follow the tree's natural trust chain. This
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supports cases where siblings are permitted to execute code on one another, or
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where isolated processes can connect to a listener and communicate with an
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already established established tree.
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Future
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######
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The current routing approach is incomplete, since routes to downstream contexts
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are not propagated upwards when a descendant of the master context establishes
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a new child context, but that is okay for now, since child contexts cannot
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currently allocate new context IDs anyway.
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Differences Between Master And Child Brokers
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############################################
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The main difference between :py:class:`mitogen.core.Broker` and
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:py:class:`mitogen.master.Broker` is that when the stream connection to the
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parent is lost in a child, the broker will trigger its own shutdown.
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The Module Importer
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-------------------
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:py:class:`mitogen.core.Importer` is still a work in progress, as there
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are a variety of approaches to implementing it, and the present implementation
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is not pefectly efficient in every case.
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It operates by intercepting :keyword:`import` statements via
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:py:data:`sys.meta_path`, asking Python if it can satisfy the import by itself,
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and if not, indicating to Python that it is capable of loading the module.
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In :py:meth:`load_module() <mitogen.core.Importer.load_module>` an RPC is
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started to the parent context, requesting the module source code by way of a
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:py:data:`GET_MODULE <mitogen.core.GET_MODULE>`. If the parent context does not
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have the module available, it recursively forwards the request upstream, while
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avoiding duplicate requests for the same module from its own threads and any
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child contexts.
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Neutralizing :py:mod:`__main__`
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###############################
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To avoid accidental execution of the :py:mod:`__main__` module's code in a
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slave context, when serving the source of the main module, Mitogen removes any
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code occurring after the first conditional that looks like a standard
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:py:mod:`__main__` execution guard:
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.. code-block:: python
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# Code that looks like this is stripped from __main__.
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if __name__ == '__main__':
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run_some_code()
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This is a hack, but it's the least annoying hack I've found for the problem
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yet.
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Avoiding Negative Imports
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#########################
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In Python 2.x where relative imports are the default, a large number of import
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requests will be made for modules that do not exist. For example:
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.. code-block:: python
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# mypkg/__init__.py
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import sys
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import os
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In Python 2.x, Python will first try to load :py:mod:`mypkg.sys` and
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:py:mod:`mypkg.os`, which do not exist, before falling back on :py:mod:`sys`
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and :py:mod:`os`.
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These negative imports present a challenge, as they introduce a large number of
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pointless network round-trips. Therefore in addition to the
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:py:mod:`zlib`-compressed source, for packages the master sends along a list of
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child modules known to exist.
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Before indicating it can satisfy an import request,
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:py:class:`mitogen.core.Importer` first checks to see if the module belongs to
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a package it has previously imported, and if so, ignores the request if the
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module does not appear in the enumeration of child modules belonging to the
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package that was provided by the master.
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.. _import-preloading:
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Import Preloading
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#################
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.. currentmodule:: mitogen.core
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To further avoid round-trips, when a module or package is requested by a child,
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its bytecode is scanned in the master to find all the module's
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:keyword:`import` statements, and of those, which associated modules appear to
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have been loaded in the master's :py:data:`sys.modules`.
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The :py:data:`sys.modules` check is necessary to handle various kinds of
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conditional execution, for example, when a module's code guards an
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:keyword:`import` statement based on the active Python runtime version,
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operating system, or optional third party dependencies.
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Before replying to a child's request for a module with dependencies:
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* If the request is for a package, any dependent modules used by the package
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that appear within the package itself are known to be missing from the child,
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since the child requested the top-level package module, therefore they are
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pre-loaded into the child using :py:data:`LOAD_MODULE` messages before
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sending the :py:data:`LOAD_MODULE` message for the requested package module
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itself. In this way, the child will already have dependent modules cached by
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the time it receives the requested module, avoiding one round-trip for each
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dependency.
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For example, when a child requests the :py:mod:`django` package, and the master
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determines the :py:mod:`django` module code in the master has :keyword:`import`
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statements for :py:mod:`django.utils`, :py:mod:`django.utils.lru_cache`, and
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:py:mod:`django.utils.version`,
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and that execution of the module code on the master caused those modules to
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appear in the master's :py:data:`sys.modules`, there is high probability
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execution of the :py:mod:`django` module code in the child will cause the
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same modules to be loaded. Since all those modules exist within the
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:py:mod:`django` package, and we already know the child lacks that package,
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it is safe to assume the child will make follow-up requests for those modules
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too.
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In the example, 4 round-trips are replaced by 1 round-trip.
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For any package module ever requested by a child, the parent keeps a note of
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the name of the package for one final optimization:
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* If the request is for a sub-module of a package, and it is known the child
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loaded the package's implementation from the parent, then any dependent
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modules of the requested module at any nesting level within the package that
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is known to be missing are sent using :py:data:`LOAD_MODULE` messages before
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sending the :py:data:`LOAD_MODULE` message for the requested module, avoiding
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1 round-trip for each dependency within the same top-level package.
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For example, when a child has previously requested the :py:mod:`django`
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package module, the parent knows the package was completely absent on the
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child. Therefore when the child subsequently requests the
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:py:mod:`django.db` package module, it is safe to assume the child will
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generate subsequent :py:data:`GET_MODULE` requests for the 2
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:py:mod:`django.conf`, 3 :py:mod:`django.core`, 2 :py:mod:`django.db`, 3
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:py:mod:`django.dispatch`, and 7 :py:mod:`django.utils` indirect dependencies
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for :py:mod:`django.db`.
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In the example, 17 round-trips are replaced by 1 round-trip.
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The method used to detect import statements is similar to the standard library
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:py:mod:`modulefinder` module: rather than analyze module source code,
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:ref:`IMPORT_NAME <python:bytecodes>` opcodes are extracted from the module's
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bytecode. This is since clean source analysis methods (:py:mod:`ast` and
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:py:mod:`compiler`) are an order of magnitude slower, and incompatible across
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major Python versions.
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Concurrency
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###########
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Duplicate requests must never be issued to the parent, either due to a local
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import or any :py:data:`GET_MODULE` originating from a child. This lets parents
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assume a module requested once by a downstream connection need never be
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re-sent, for example, if it appears as a preloading dependency in a subsequent
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:py:data:`GET_MODULE`, or had been requested immediately after being sent as a
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preloading dependency for an unrelated request by a descendent.
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Therefore each tree layer must deduplicate :py:data:`GET_MODULE` requests, and
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synchronize their descendents and local threads on corresponding
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:py:data:`LOAD_MODULE` responses from the parent.
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In each context, pending requests are serialized by a
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:py:class:`threading.Lock` within :py:class:`mitogen.core.Importer`, which may
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only be held for operations that cannot block, since :py:class:`ModuleForwarder
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<mitogen.master.ModuleForwarder>` must acquire it while synchronizing
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:py:data:`GET_MODULE` requests from children on the IO multiplexer thread.
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Requests From Local Threads
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~~~~~~~~~~~~~~~~~~~~~~~~~~~
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When Mitogen begins satisfying an import, it is known the module has never been
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imported in the local process. :py:class:`Importer <mitogen.core.Importer>`
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executes under the runtime importer lock, ensuring :py:keyword:`import`
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statements executing in local threads are serialized.
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.. note::
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In Python 2, :py:exc:`ImportError` is raised when :py:keyword:`import` is
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attempted while the runtime import lock is held by another thread,
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therefore imports must be serialized by only attempting them from the main
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(:py:data:`CALL_FUNCTION`) thread.
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The problem is most likely to manifest in third party libraries that lazily
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import optional dependencies at runtime from a non-main thread. The
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workaround is to explicitly import those dependencies from the main thread
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before initializing the third party library.
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This was fixed in Python 3.5, but Python 3.x is not yet supported. See
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`Python Issue #9260`_.
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.. _Python Issue #9260: https://bugs.python.org/issue9260
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While holding its own lock, :py:class:`Importer <mitogen.core.Importer>`
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checks if the source is not yet cached, determines if an in-flight
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:py:data:`GET_MODULE` exists for it, starting one if none exists, adds itself
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to a list of callbacks fired when a corresponding :py:data:`LOAD_MODULE`
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arrives from the parent, then sleeps waiting for the callback.
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When the source becomes available, the module is constructed on the calling
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thread using the best practice documented in `PEP 302`_.
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.. _PEP 302: https://www.python.org/dev/peps/pep-0302/
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Requests From Children
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~~~~~~~~~~~~~~~~~~~~~~
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As with local imports, when :py:data:`GET_MODULE` is received from a child,
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while holding the :py:class:`Importer <mitogen.core.Importer>` lock,
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:py:class:`ModuleForwarder <mitogen.master.ModuleForwarder>` checks if the
|
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source is not yet cached, determines if an in-flight :py:data:`GET_MODULE`
|
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toward the parent exists for it, starting one if none exists, then adds a
|
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completion handler to the list of callbacks fired when a corresponding
|
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:py:data:`LOAD_MODULE` arrives from the parent.
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When the source becomes available, the completion handler issues corresponding
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:py:data:`LOAD_MODULE` messages toward the child for the requested module after
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any required for dependencies known to be absent from the child.
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Since intermediaries do not know a module's dependencies until the module's
|
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source arrives, it is not possible to preemptively issue :py:data:`LOAD_MODULE`
|
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for those dependencies toward a requesting child as they become available from
|
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the parent at the intermediary. This creates needless network serialization and
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latency that should be addressed in a future design.
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Child Module Enumeration
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|
########################
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Package children are enumerated using :py:func:`pkgutil.iter_modules`.
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Use Of Threads
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--------------
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The package always runs the IO multiplexer in a thread. This is so the
|
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multiplexer retains control flow in order to shut down gracefully, say, if the
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user's code has hung and the master context has disconnected.
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While it is possible for the IO multiplexer to recover control of a hung
|
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function call on UNIX using for example :py:mod:`signal.SIGALRM <signal>`, this
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mechanism is not portable to non-UNIX operating systems, and does not work in
|
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every case, for example when Python blocks signals during a variety of
|
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:py:mod:`threading` package operations.
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At some point it is likely Mitogen will be extended to support children running
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on Windows. When that happens, it would be nice if the process model on Windows
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and UNIX did not differ, and in fact the code used on both were identical.
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Waking Sleeping Threads
|
|
#######################
|
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Due to fundamental deficiencies in Python 2's threading implementation, it is
|
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not possible to block waiting on synchronization objects sanely. Two major
|
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problems exist:
|
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* Sleeping with no timeout set causes signals to be blocked, preventing the
|
|
user from using CTRL+C to terminate the process.
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* Sleeping with a timeout set internally makes use of polling, with an
|
|
exponential backoff that eventually results in the thread sleeping
|
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unconditionally in 50ms increments. . This is a huge source of latency that
|
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quickly multiplies.
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As the UNIX self-pipe trick must already be employed to wake the broker thread
|
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from its select loop, Mitogen reuses this technique to wake any thread
|
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synchronization primitive exposed by the library, embodied in a queue-like
|
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abstraction called a :py:class:`mitogen.core.Latch`.
|
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Unfortunately it is commonplace for hosts to enforce severe per-process file
|
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descriptors limits, so aside from being inefficient, it is impossible in the
|
|
usual case to create a pair of descriptors for every waitable object, which for
|
|
example includes the result of every single asynchronous function call.
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For this reason self-pipes are created on a per-thread basis, with their
|
|
associated :py:func:`socketpairs <socket.socketpair>` kept in thread-local
|
|
storage. When a latch wishes to sleep its thread, this pair is created
|
|
on-demand and temporarily associated with it only for the duration of the
|
|
sleep.
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|
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Python's garbage collector is relied on to clean up by calling the pair's
|
|
destructor on thread exit. There does not otherwise seem to be a robust method
|
|
to trigger cleanup code on arbitrary threads.
|
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|
To summarize, file descriptor usage is bounded by the number of threads rather
|
|
than the number of waitables, which is a much smaller number, however it also
|
|
means that Mitogen requires twice as many file descriptors as there are user
|
|
threads, with a minimum of 4 required in any configuration.
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.. rubric:: Footnotes
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|
|
.. [#f1] Compression may seem redundant, however it is basically free and reducing IO
|
|
is always a good idea. The 33% / 200 byte saving may mean the presence or
|
|
absence of an additional frame on the network, or in real world terms after
|
|
accounting for SSH overhead, around a 2% reduced chance of a stall during
|
|
connection setup due to a dropped frame.
|