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.. _parallel_connections:
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==============================================
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Connection Diagrams of The IPython ZMQ Cluster
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==============================================
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This is a quick summary and illustration of the connections involved in the ZeroMQ based
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IPython cluster for parallel computing.
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All Connections
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===============
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The IPython cluster consists of a Controller, and one or more each of clients and engines.
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The goal of the Controller is to manage and monitor the connections and communications
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between the clients and the engines. The Controller is no longer a single process entity,
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but rather a collection of processes - specifically one Hub, and 4 (or more) Schedulers.
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It is important for security/practicality reasons that all connections be inbound to the
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controller processes. The arrows in the figures indicate the direction of the
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connection.
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.. figure:: figs/allconnections.png
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:width: 432px
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:alt: IPython cluster connections
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:align: center
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All the connections involved in connecting one client to one engine.
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The Controller consists of 1-5 processes. Central to the cluster is the **Hub**, which monitors
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engine state, execution traffic, and handles registration and notification. The Hub includes a
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Heartbeat Monitor for keeping track of engines that are alive. Outside the Hub are 4
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**Schedulers**. These devices are very small pure-C MonitoredQueue processes (or optionally
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threads) that relay messages very fast, but also send a copy of each message along a side socket
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to the Hub. The MUX queue and Control queue are MonitoredQueue ØMQ devices which relay
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explicitly addressed messages from clients to engines, and their replies back up. The Balanced
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queue performs load-balancing destination-agnostic scheduling. It may be a MonitoredQueue
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device, but may also be a Python Scheduler that behaves externally in an identical fashion to MQ
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devices, but with additional internal logic. stdout/err are also propagated from the Engines to
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the clients via a PUB/SUB MonitoredQueue.
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Registration
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------------
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.. figure:: figs/queryfade.png
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:width: 432px
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:alt: IPython Registration connections
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:align: center
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Engines and Clients only need to know where the Query ``ROUTER`` is located to start
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connecting.
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Once a controller is launched, the only information needed for connecting clients and/or
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engines is the IP/port of the Hub's ``ROUTER`` socket called the Registrar. This socket
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handles connections from both clients and engines, and replies with the remaining
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information necessary to establish the remaining connections. Clients use this same socket for
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querying the Hub for state information.
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Heartbeat
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---------
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.. figure:: figs/hbfade.png
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:width: 432px
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:alt: IPython Heartbeat connections
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:align: center
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The heartbeat sockets.
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The heartbeat process has been described elsewhere. To summarize: the Heartbeat Monitor
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publishes a distinct message periodically via a ``PUB`` socket. Each engine has a
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``zmq.FORWARDER`` device with a ``SUB`` socket for input, and ``DEALER`` socket for output.
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The ``SUB`` socket is connected to the ``PUB`` socket labeled *ping*, and the ``DEALER`` is
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connected to the ``ROUTER`` labeled *pong*. This results in the same message being relayed
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back to the Heartbeat Monitor with the addition of the ``DEALER`` prefix. The Heartbeat
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Monitor receives all the replies via an ``ROUTER`` socket, and identifies which hearts are
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still beating by the ``zmq.IDENTITY`` prefix of the ``DEALER`` sockets, which information
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the Hub uses to notify clients of any changes in the available engines.
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Schedulers
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----------
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.. figure:: figs/queuefade.png
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:width: 432px
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:alt: IPython Queue connections
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:align: center
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Control message scheduler on the left, execution (apply) schedulers on the right.
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The controller has at least three Schedulers. These devices are primarily for
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relaying messages between clients and engines, but the Hub needs to see those
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messages for its own purposes. Since no Python code may exist between the two sockets in a
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queue, all messages sent through these queues (both directions) are also sent via a
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``PUB`` socket to a monitor, which allows the Hub to monitor queue traffic without
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interfering with it.
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For tasks, the engine need not be specified. Messages sent to the ``ROUTER`` socket from the
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client side are assigned to an engine via ZMQ's ``DEALER`` round-robin load balancing.
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Engine replies are directed to specific clients via the IDENTITY of the client, which is
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received as a prefix at the Engine.
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For Multiplexing, ``ROUTER`` is used for both in and output sockets in the device. Clients must
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specify the destination by the ``zmq.IDENTITY`` of the ``ROUTER`` socket connected to
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the downstream end of the device.
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At the Kernel level, both of these ``ROUTER`` sockets are treated in the same way as the ``REP``
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socket in the serial version (except using ZMQStreams instead of explicit sockets).
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Execution can be done in a load-balanced (engine-agnostic) or multiplexed (engine-specified)
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manner. The sockets on the Client and Engine are the same for these two actions, but the
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scheduler used determines the actual behavior. This routing is done via the ``zmq.IDENTITY`` of
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the upstream sockets in each MonitoredQueue.
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IOPub
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-----
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.. figure:: figs/iopubfade.png
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:width: 432px
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:alt: IOPub connections
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:align: center
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stdout/err are published via a ``PUB/SUB`` MonitoredQueue
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On the kernels, stdout/stderr are captured and published via a ``PUB`` socket. These ``PUB``
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sockets all connect to a ``SUB`` socket input of a MonitoredQueue, which subscribes to all
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messages. They are then republished via another ``PUB`` socket, which can be
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subscribed by the clients.
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Client connections
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------------------
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.. figure:: figs/queryfade.png
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:width: 432px
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:alt: IPython client query connections
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:align: center
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Clients connect to an ``ROUTER`` socket to query the hub.
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The hub's registrar ``ROUTER`` socket also listens for queries from clients as to queue status,
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and control instructions. Clients connect to this socket via an ``DEALER`` during registration.
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.. figure:: figs/notiffade.png
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:width: 432px
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:alt: IPython Registration connections
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:align: center
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Engine registration events are published via a ``PUB`` socket.
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The Hub publishes all registration/unregistration events via a ``PUB`` socket. This
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allows clients to stay up to date with what engines are available by subscribing to the
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feed with a ``SUB`` socket. Other processes could selectively subscribe to just
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registration or unregistration events.
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