parallel_intro.txt
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r3586 | .. _ip1par: | ||
| ============================ | ||||
| Overview and getting started | ||||
| ============================ | ||||
| Introduction | ||||
| ============ | ||||
| This section gives an overview of IPython's sophisticated and powerful | ||||
| architecture for parallel and distributed computing. This architecture | ||||
| abstracts out parallelism in a very general way, which enables IPython to | ||||
| support many different styles of parallelism including: | ||||
| * Single program, multiple data (SPMD) parallelism. | ||||
| * Multiple program, multiple data (MPMD) parallelism. | ||||
| * Message passing using MPI. | ||||
| * Task farming. | ||||
| * Data parallel. | ||||
| * Combinations of these approaches. | ||||
| * Custom user defined approaches. | ||||
| Most importantly, IPython enables all types of parallel applications to | ||||
| be developed, executed, debugged and monitored *interactively*. Hence, | ||||
| the ``I`` in IPython. The following are some example usage cases for IPython: | ||||
| * Quickly parallelize algorithms that are embarrassingly parallel | ||||
| using a number of simple approaches. Many simple things can be | ||||
| parallelized interactively in one or two lines of code. | ||||
| * Steer traditional MPI applications on a supercomputer from an | ||||
| IPython session on your laptop. | ||||
| * Analyze and visualize large datasets (that could be remote and/or | ||||
| distributed) interactively using IPython and tools like | ||||
| matplotlib/TVTK. | ||||
| * Develop, test and debug new parallel algorithms | ||||
| (that may use MPI) interactively. | ||||
| * Tie together multiple MPI jobs running on different systems into | ||||
| one giant distributed and parallel system. | ||||
| * Start a parallel job on your cluster and then have a remote | ||||
| collaborator connect to it and pull back data into their | ||||
| local IPython session for plotting and analysis. | ||||
| * Run a set of tasks on a set of CPUs using dynamic load balancing. | ||||
| Architecture overview | ||||
| ===================== | ||||
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r3591 | The IPython architecture consists of four components: | ||
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| * The IPython engine. | ||||
| * The IPython controller. | ||||
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r3591 | * The controller client. | ||
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r3591 | These components live in the :mod:`IPython.zmq.parallel` package and are | ||
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r3586 | installed with IPython. They do, however, have additional dependencies | ||
| that must be installed. For more information, see our | ||||
| :ref:`installation documentation <install_index>`. | ||||
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r3591 | .. TODO: include zmq in install_index | ||
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r3586 | IPython engine | ||
| --------------- | ||||
| The IPython engine is a Python instance that takes Python commands over a | ||||
| network connection. Eventually, the IPython engine will be a full IPython | ||||
| interpreter, but for now, it is a regular Python interpreter. The engine | ||||
| can also handle incoming and outgoing Python objects sent over a network | ||||
| connection. When multiple engines are started, parallel and distributed | ||||
| computing becomes possible. An important feature of an IPython engine is | ||||
| that it blocks while user code is being executed. Read on for how the | ||||
| IPython controller solves this problem to expose a clean asynchronous API | ||||
| to the user. | ||||
| IPython controller | ||||
| ------------------ | ||||
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r3600 | The IPython controller provides an interface for working with a set of engines. At a | ||
| general level, the controller is a collection of processes to which IPython engines and | ||||
| clients can connect. The controller is composed of a :class:`Hub` and a collection of | ||||
| :class:`Schedulers`. These Schedulers are typically run in separate processes but on the | ||||
| same machine as the Hub, but can be run anywhere from local threads or on remote machines. | ||||
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| The controller also provides a single point of contact for users who wish to | ||||
| utilize the engines connected to the controller. There are different ways of | ||||
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r3591 | working with a controller. In IPython, all of these models are implemented via | ||
| the client's :meth:`.Client.apply` method, with various arguments, or | ||||
| constructing :class:`.View` objects to represent subsets of engines. The two | ||||
| primary models for interacting with engines are: | ||||
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r3591 | * A MUX interface, where engines are addressed explicitly. | ||
| * A Task interface, where the Scheduler is trusted with assigning work to | ||||
| appropriate engines. | ||||
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r3591 | Advanced users can readily extend the View models to enable other | ||
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r3586 | styles of parallelism. | ||
| .. note:: | ||||
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r3591 | A single controller and set of engines can be used with multiple models | ||
| simultaneously. This opens the door for lots of interesting things. | ||||
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r3600 | The Hub | ||
| ******* | ||||
| The center of an IPython cluster is the Controller Hub. This is the process that keeps | ||||
| track of engine connections, schedulers, clients, as well as all task requests and | ||||
| results. The primary role of the Hub is to facilitate queries of the cluster state, and | ||||
| minimize the necessary information required to establish the many connections involved in | ||||
| connecting new clients and engines. | ||||
| Schedulers | ||||
| ********** | ||||
| All actions that can be performed on the engine go through a Scheduler. While the engines | ||||
| themselves block when user code is run, the schedulers hide that from the user to provide | ||||
| a fully asynchronous interface to a set of engines. | ||||
| IPython client | ||||
| -------------- | ||||
| There is one primary object, the :class:`~.parallel.client.Client`, for connecting to a | ||||
| controller. For each model, there is a corresponding view. These views allow users to | ||||
| interact with a set of engines through the interface. Here are the two default views: | ||||
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r3591 | * The :class:`DirectView` class for explicit addressing. | ||
| * The :class:`LoadBalancedView` class for destination-agnostic scheduling. | ||||
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| Security | ||||
| -------- | ||||
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r3591 | IPython uses ZeroMQ for networking, which has provided many advantages, but | ||
| one of the setbacks is its utter lack of security [ZeroMQ]_. By default, no IPython | ||||
| connections are secured, but open ports only listen on localhost. The only | ||||
| source of security for IPython is via ssh-tunnel. IPython supports both shell | ||||
| (`openssh`) and `paramiko` based tunnels for connections. | ||||
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| In our architecture, the controller is the only process that listens on | ||||
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r3591 | network ports, and is thus the main point of vulnerability. The standard model | ||
| for secure connections is to designate that the controller listen on | ||||
| localhost, and use ssh-tunnels on the same machine to connect clients and/or | ||||
| engines. | ||||
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r3591 | .. warning:: | ||
| Even at its most secure, the Controller listens on ports on localhost, and | ||||
| every time you make a tunnel, you open a localhost port on the connecting | ||||
| machine that points to the Controller. If localhost on the Controller's | ||||
| machine, or the machine of any client or engine, is untrusted, then your | ||||
| Controller is insecure. There is no way around this with ZeroMQ. | ||||
| .. TODO: edit parallelsecurity | ||||
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r3586 | A detailed description of the security model and its implementation in IPython | ||
| can be found :ref:`here <parallelsecurity>`. | ||||
| Getting Started | ||||
| =============== | ||||
| To use IPython for parallel computing, you need to start one instance of the | ||||
| controller and one or more instances of the engine. Initially, it is best to | ||||
| simply start a controller and engines on a single host using the | ||||
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r3591 | :command:`ipclusterz` command. To start a controller and 4 engines on your | ||
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r3586 | localhost, just do:: | ||
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r3591 | $ ipclusterz -n 4 | ||
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| More details about starting the IPython controller and engines can be found | ||||
| :ref:`here <parallel_process>` | ||||
| Once you have started the IPython controller and one or more engines, you | ||||
| are ready to use the engines to do something useful. To make sure | ||||
| everything is working correctly, try the following commands: | ||||
| .. sourcecode:: ipython | ||||
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r3591 | In [1]: from IPython.zmq.parallel import client | ||
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r3591 | In [2]: c = client.Client() | ||
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r3591 | In [4]: c.ids | ||
| Out[4]: set([0, 1, 2, 3]) | ||||
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r3591 | In [5]: c.apply(lambda : "Hello, World", targets='all', block=True) | ||
| Out[5]: {0: 'Hello, World', 1: 'Hello, World', 2: 'Hello, World', 3: | ||||
| 'Hello, World'} | ||||
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r3600 | Remember, a client needs to be able to see the Hub. So if they | ||
| are on a different machine, and you have ssh access to that machine, | ||||
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r3594 | then you would connect to it with:: | ||
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r3591 | .. sourcecode:: ipython | ||
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r3600 | In [2]: c = client.Client(sshserver='myhub.example.com') | ||
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r3600 | Where 'myhub.example.com' is the url or IP address of the machine on | ||
| which the Hub process is running. | ||||
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r3591 | You are now ready to learn more about the :ref:`MUX | ||
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r3586 | <parallelmultiengine>` and :ref:`Task <paralleltask>` interfaces to the | ||
| controller. | ||||
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r3591 | .. [ZeroMQ] ZeroMQ. http://www.zeromq.org | ||