parallel_winhpc.txt
334 lines
| 13.8 KiB
| text/plain
|
TextLexer
MinRK
|
r3586 | ============================================ | ||
| Getting started with Windows HPC Server 2008 | ||||
| ============================================ | ||||
|
MinRK
|
r3597 | .. note:: | ||
| Not adapted to zmq yet | ||||
|
MinRK
|
r3586 | Introduction | ||
| ============ | ||||
| The Python programming language is an increasingly popular language for | ||||
| numerical computing. This is due to a unique combination of factors. First, | ||||
| Python is a high-level and *interactive* language that is well matched to | ||||
| interactive numerical work. Second, it is easy (often times trivial) to | ||||
| integrate legacy C/C++/Fortran code into Python. Third, a large number of | ||||
| high-quality open source projects provide all the needed building blocks for | ||||
| numerical computing: numerical arrays (NumPy), algorithms (SciPy), 2D/3D | ||||
| Visualization (Matplotlib, Mayavi, Chaco), Symbolic Mathematics (Sage, Sympy) | ||||
| and others. | ||||
| The IPython project is a core part of this open-source toolchain and is | ||||
| focused on creating a comprehensive environment for interactive and | ||||
| exploratory computing in the Python programming language. It enables all of | ||||
| the above tools to be used interactively and consists of two main components: | ||||
| * An enhanced interactive Python shell with support for interactive plotting | ||||
| and visualization. | ||||
| * An architecture for interactive parallel computing. | ||||
| With these components, it is possible to perform all aspects of a parallel | ||||
| computation interactively. This type of workflow is particularly relevant in | ||||
| scientific and numerical computing where algorithms, code and data are | ||||
| continually evolving as the user/developer explores a problem. The broad | ||||
| treads in computing (commodity clusters, multicore, cloud computing, etc.) | ||||
| make these capabilities of IPython particularly relevant. | ||||
| While IPython is a cross platform tool, it has particularly strong support for | ||||
| Windows based compute clusters running Windows HPC Server 2008. This document | ||||
| describes how to get started with IPython on Windows HPC Server 2008. The | ||||
| content and emphasis here is practical: installing IPython, configuring | ||||
| IPython to use the Windows job scheduler and running example parallel programs | ||||
| interactively. A more complete description of IPython's parallel computing | ||||
| capabilities can be found in IPython's online documentation | ||||
Thomas Kluyver
|
r4086 | (http://ipython.org/documentation.html). | ||
|
MinRK
|
r3586 | |||
| Setting up your Windows cluster | ||||
| =============================== | ||||
| This document assumes that you already have a cluster running Windows | ||||
| HPC Server 2008. Here is a broad overview of what is involved with setting up | ||||
| such a cluster: | ||||
| 1. Install Windows Server 2008 on the head and compute nodes in the cluster. | ||||
| 2. Setup the network configuration on each host. Each host should have a | ||||
| static IP address. | ||||
| 3. On the head node, activate the "Active Directory Domain Services" role | ||||
| and make the head node the domain controller. | ||||
| 4. Join the compute nodes to the newly created Active Directory (AD) domain. | ||||
| 5. Setup user accounts in the domain with shared home directories. | ||||
| 6. Install the HPC Pack 2008 on the head node to create a cluster. | ||||
| 7. Install the HPC Pack 2008 on the compute nodes. | ||||
| More details about installing and configuring Windows HPC Server 2008 can be | ||||
| found on the Windows HPC Home Page (http://www.microsoft.com/hpc). Regardless | ||||
| of what steps you follow to set up your cluster, the remainder of this | ||||
| document will assume that: | ||||
| * There are domain users that can log on to the AD domain and submit jobs | ||||
| to the cluster scheduler. | ||||
| * These domain users have shared home directories. While shared home | ||||
| directories are not required to use IPython, they make it much easier to | ||||
| use IPython. | ||||
| Installation of IPython and its dependencies | ||||
| ============================================ | ||||
| IPython and all of its dependencies are freely available and open source. | ||||
| These packages provide a powerful and cost-effective approach to numerical and | ||||
| scientific computing on Windows. The following dependencies are needed to run | ||||
| IPython on Windows: | ||||
|
MinRK
|
r3671 | * Python 2.6 or 2.7 (http://www.python.org) | ||
|
MinRK
|
r3586 | * pywin32 (http://sourceforge.net/projects/pywin32/) | ||
| * PyReadline (https://launchpad.net/pyreadline) | ||||
|
MinRK
|
r3671 | * pyzmq (http://github.com/zeromq/pyzmq/downloads) | ||
|
Thomas Kluyver
|
r4086 | * IPython (http://ipython.org) | ||
|
MinRK
|
r3586 | |||
| In addition, the following dependencies are needed to run the demos described | ||||
| in this document. | ||||
| * NumPy and SciPy (http://www.scipy.org) | ||||
| * Matplotlib (http://matplotlib.sourceforge.net/) | ||||
| The easiest way of obtaining these dependencies is through the Enthought | ||||
| Python Distribution (EPD) (http://www.enthought.com/products/epd.php). EPD is | ||||
| produced by Enthought, Inc. and contains all of these packages and others in a | ||||
| single installer and is available free for academic users. While it is also | ||||
| possible to download and install each package individually, this is a tedious | ||||
| process. Thus, we highly recommend using EPD to install these packages on | ||||
| Windows. | ||||
| Regardless of how you install the dependencies, here are the steps you will | ||||
| need to follow: | ||||
| 1. Install all of the packages listed above, either individually or using EPD | ||||
| on the head node, compute nodes and user workstations. | ||||
|
MinRK
|
r3671 | 2. Make sure that :file:`C:\\Python27` and :file:`C:\\Python27\\Scripts` are | ||
|
MinRK
|
r3586 | in the system :envvar:`%PATH%` variable on each node. | ||
| 3. Install the latest development version of IPython. This can be done by | ||||
| downloading the the development version from the IPython website | ||||
|
Thomas Kluyver
|
r4086 | (http://ipython.org) and following the installation instructions. | ||
|
MinRK
|
r3586 | |||
| Further details about installing IPython or its dependencies can be found in | ||||
|
Thomas Kluyver
|
r4086 | the online IPython documentation (http://ipython.org/documentation.html) | ||
|
MinRK
|
r3586 | Once you are finished with the installation, you can try IPython out by | ||
| opening a Windows Command Prompt and typing ``ipython``. This will | ||||
| start IPython's interactive shell and you should see something like the | ||||
| following screenshot: | ||||
|
MinRK
|
r3671 | .. image:: ipython_shell.* | ||
|
MinRK
|
r3586 | |||
| Starting an IPython cluster | ||||
| =========================== | ||||
| To use IPython's parallel computing capabilities, you will need to start an | ||||
| IPython cluster. An IPython cluster consists of one controller and multiple | ||||
| engines: | ||||
| IPython controller | ||||
| The IPython controller manages the engines and acts as a gateway between | ||||
| the engines and the client, which runs in the user's interactive IPython | ||||
| session. The controller is started using the :command:`ipcontroller` | ||||
| command. | ||||
| IPython engine | ||||
| IPython engines run a user's Python code in parallel on the compute nodes. | ||||
| Engines are starting using the :command:`ipengine` command. | ||||
| Once these processes are started, a user can run Python code interactively and | ||||
| in parallel on the engines from within the IPython shell using an appropriate | ||||
| client. This includes the ability to interact with, plot and visualize data | ||||
| from the engines. | ||||
|
MinRK
|
r3672 | IPython has a command line program called :command:`ipcluster` that automates | ||
|
MinRK
|
r3586 | all aspects of starting the controller and engines on the compute nodes. | ||
|
MinRK
|
r3672 | :command:`ipcluster` has full support for the Windows HPC job scheduler, | ||
| meaning that :command:`ipcluster` can use this job scheduler to start the | ||||
|
MinRK
|
r3586 | controller and engines. In our experience, the Windows HPC job scheduler is | ||
| particularly well suited for interactive applications, such as IPython. Once | ||||
|
MinRK
|
r3672 | :command:`ipcluster` is configured properly, a user can start an IPython | ||
|
MinRK
|
r3586 | cluster from their local workstation almost instantly, without having to log | ||
| on to the head node (as is typically required by Unix based job schedulers). | ||||
| This enables a user to move seamlessly between serial and parallel | ||||
| computations. | ||||
|
MinRK
|
r3672 | In this section we show how to use :command:`ipcluster` to start an IPython | ||
|
MinRK
|
r3586 | cluster using the Windows HPC Server 2008 job scheduler. To make sure that | ||
|
MinRK
|
r3672 | :command:`ipcluster` is installed and working properly, you should first try | ||
|
MinRK
|
r3586 | to start an IPython cluster on your local host. To do this, open a Windows | ||
| Command Prompt and type the following command:: | ||||
|
MinRK
|
r3990 | ipcluster start n=2 | ||
|
MinRK
|
r3586 | |||
| You should see a number of messages printed to the screen, ending with | ||||
| "IPython cluster: started". The result should look something like the following | ||||
| screenshot: | ||||
|
MinRK
|
r3671 | .. image:: ipcluster_start.* | ||
|
MinRK
|
r3586 | |||
| At this point, the controller and two engines are running on your local host. | ||||
| This configuration is useful for testing and for situations where you want to | ||||
| take advantage of multiple cores on your local computer. | ||||
|
MinRK
|
r3672 | Now that we have confirmed that :command:`ipcluster` is working properly, we | ||
|
MinRK
|
r3586 | describe how to configure and run an IPython cluster on an actual compute | ||
| cluster running Windows HPC Server 2008. Here is an outline of the needed | ||||
| steps: | ||||
|
MinRK
|
r4038 | 1. Create a cluster profile using: ``ipython profile create --parallel profile=mycluster`` | ||
|
MinRK
|
r3586 | |||
| 2. Edit configuration files in the directory :file:`.ipython\\cluster_mycluster` | ||||
|
MinRK
|
r3990 | 3. Start the cluster using: ``ipcluser start profile=mycluster n=32`` | ||
|
MinRK
|
r3586 | |||
| Creating a cluster profile | ||||
| -------------------------- | ||||
| In most cases, you will have to create a cluster profile to use IPython on a | ||||
| cluster. A cluster profile is a name (like "mycluster") that is associated | ||||
| with a particular cluster configuration. The profile name is used by | ||||
|
MinRK
|
r3672 | :command:`ipcluster` when working with the cluster. | ||
|
MinRK
|
r3586 | |||
| Associated with each cluster profile is a cluster directory. This cluster | ||||
| directory is a specially named directory (typically located in the | ||||
| :file:`.ipython` subdirectory of your home directory) that contains the | ||||
| configuration files for a particular cluster profile, as well as log files and | ||||
| security keys. The naming convention for cluster directories is: | ||||
|
MinRK
|
r4024 | :file:`profile_<profile name>`. Thus, the cluster directory for a profile named | ||
|
MinRK
|
r3586 | "foo" would be :file:`.ipython\\cluster_foo`. | ||
| To create a new cluster profile (named "mycluster") and the associated cluster | ||||
| directory, type the following command at the Windows Command Prompt:: | ||||
|
Thomas Kluyver
|
r4196 | ipython profile create --parallel --profile=mycluster | ||
|
MinRK
|
r3586 | |||
| The output of this command is shown in the screenshot below. Notice how | ||||
|
MinRK
|
r3672 | :command:`ipcluster` prints out the location of the newly created cluster | ||
|
MinRK
|
r3586 | directory. | ||
|
MinRK
|
r3671 | .. image:: ipcluster_create.* | ||
|
MinRK
|
r3586 | |||
| Configuring a cluster profile | ||||
| ----------------------------- | ||||
| Next, you will need to configure the newly created cluster profile by editing | ||||
| the following configuration files in the cluster directory: | ||||
|
MinRK
|
r3672 | * :file:`ipcluster_config.py` | ||
|
MinRK
|
r3586 | * :file:`ipcontroller_config.py` | ||
| * :file:`ipengine_config.py` | ||||
|
MinRK
|
r3672 | When :command:`ipcluster` is run, these configuration files are used to | ||
|
MinRK
|
r3586 | determine how the engines and controller will be started. In most cases, | ||
| you will only have to set a few of the attributes in these files. | ||||
|
MinRK
|
r3672 | To configure :command:`ipcluster` to use the Windows HPC job scheduler, you | ||
|
MinRK
|
r3586 | will need to edit the following attributes in the file | ||
|
MinRK
|
r3672 | :file:`ipcluster_config.py`:: | ||
|
MinRK
|
r3586 | |||
|
MinRK
|
r3672 | # Set these at the top of the file to tell ipcluster to use the | ||
|
MinRK
|
r3586 | # Windows HPC job scheduler. | ||
|
MinRK
|
r4059 | c.IPClusterStart.controller_launcher = \ | ||
|
MinRK
|
r3673 | 'IPython.parallel.apps.launcher.WindowsHPCControllerLauncher' | ||
|
MinRK
|
r4059 | c.IPClusterEngines.engine_launcher = \ | ||
|
MinRK
|
r3673 | 'IPython.parallel.apps.launcher.WindowsHPCEngineSetLauncher' | ||
|
MinRK
|
r3586 | |||
| # Set these to the host name of the scheduler (head node) of your cluster. | ||||
| c.WindowsHPCControllerLauncher.scheduler = 'HEADNODE' | ||||
| c.WindowsHPCEngineSetLauncher.scheduler = 'HEADNODE' | ||||
| There are a number of other configuration attributes that can be set, but | ||||
| in most cases these will be sufficient to get you started. | ||||
| .. warning:: | ||||
| If any of your configuration attributes involve specifying the location | ||||
| of shared directories or files, you must make sure that you use UNC paths | ||||
| like :file:`\\\\host\\share`. It is also important that you specify | ||||
| these paths using raw Python strings: ``r'\\host\share'`` to make sure | ||||
| that the backslashes are properly escaped. | ||||
| Starting the cluster profile | ||||
| ---------------------------- | ||||
| Once a cluster profile has been configured, starting an IPython cluster using | ||||
| the profile is simple:: | ||||
|
MinRK
|
r4608 | ipcluster start --profile=mycluster -n 32 | ||
|
MinRK
|
r3586 | |||
|
MinRK
|
r3672 | The ``-n`` option tells :command:`ipcluster` how many engines to start (in | ||
|
MinRK
|
r3586 | this case 32). Stopping the cluster is as simple as typing Control-C. | ||
| Using the HPC Job Manager | ||||
| ------------------------- | ||||
|
MinRK
|
r3672 | When ``ipcluster start`` is run the first time, :command:`ipcluster` creates | ||
|
MinRK
|
r3586 | two XML job description files in the cluster directory: | ||
| * :file:`ipcontroller_job.xml` | ||||
| * :file:`ipengineset_job.xml` | ||||
| Once these files have been created, they can be imported into the HPC Job | ||||
| Manager application. Then, the controller and engines for that profile can be | ||||
|
MinRK
|
r3672 | started using the HPC Job Manager directly, without using :command:`ipcluster`. | ||
| However, anytime the cluster profile is re-configured, ``ipcluster start`` | ||||
|
MinRK
|
r3586 | must be run again to regenerate the XML job description files. The | ||
| following screenshot shows what the HPC Job Manager interface looks like | ||||
| with a running IPython cluster. | ||||
|
MinRK
|
r3671 | .. image:: hpc_job_manager.* | ||
|
MinRK
|
r3586 | |||
| Performing a simple interactive parallel computation | ||||
| ==================================================== | ||||
| Once you have started your IPython cluster, you can start to use it. To do | ||||
| this, open up a new Windows Command Prompt and start up IPython's interactive | ||||
| shell by typing:: | ||||
| ipython | ||||
| Then you can create a :class:`MultiEngineClient` instance for your profile and | ||||
| use the resulting instance to do a simple interactive parallel computation. In | ||||
| the code and screenshot that follows, we take a simple Python function and | ||||
| apply it to each element of an array of integers in parallel using the | ||||
| :meth:`MultiEngineClient.map` method: | ||||
| .. sourcecode:: ipython | ||||
|
MinRK
|
r3666 | In [1]: from IPython.parallel import * | ||
|
MinRK
|
r3586 | |||
|
MinRK
|
r3597 | In [2]: c = MultiEngineClient(profile='mycluster') | ||
|
MinRK
|
r3586 | |||
| In [3]: mec.get_ids() | ||||
| Out[3]: [0, 1, 2, 3, 4, 5, 67, 8, 9, 10, 11, 12, 13, 14] | ||||
| In [4]: def f(x): | ||||
| ...: return x**10 | ||||
| In [5]: mec.map(f, range(15)) # f is applied in parallel | ||||
| Out[5]: | ||||
| [0, | ||||
| 1, | ||||
| 1024, | ||||
| 59049, | ||||
| 1048576, | ||||
| 9765625, | ||||
| 60466176, | ||||
| 282475249, | ||||
| 1073741824, | ||||
| 3486784401L, | ||||
| 10000000000L, | ||||
| 25937424601L, | ||||
| 61917364224L, | ||||
| 137858491849L, | ||||
| 289254654976L] | ||||
| The :meth:`map` method has the same signature as Python's builtin :func:`map` | ||||
| function, but runs the calculation in parallel. More involved examples of using | ||||
| :class:`MultiEngineClient` are provided in the examples that follow. | ||||
|
MinRK
|
r3671 | .. image:: mec_simple.* | ||
|
MinRK
|
r3586 | |||