faq.txt
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Brian E Granger
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r1256 | .. _faq: | ||
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Brian E Granger
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r1258 | ======================================== | ||
| Frequently asked questions | ||||
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Brian E Granger
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| General questions | ||||
| ================= | ||||
| Questions about parallel computing with IPython | ||||
| ================================================ | ||||
| Will IPython speed my Python code up? | ||||
| -------------------------------------- | ||||
| Yes and no. When converting a serial code to run in parallel, there often many | ||||
| difficulty questions that need to be answered, such as: | ||||
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Brian Granger
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r1677 | * How should data be decomposed onto the set of processors? | ||
| * What are the data movement patterns? | ||||
| * Can the algorithm be structured to minimize data movement? | ||||
| * Is dynamic load balancing important? | ||||
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Brian E Granger
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| We can't answer such questions for you. This is the hard (but fun) work of parallel | ||||
| computing. But, once you understand these things IPython will make it easier for you to | ||||
| implement a good solution quickly. Most importantly, you will be able to use the | ||||
| resulting parallel code interactively. | ||||
| With that said, if your problem is trivial to parallelize, IPython has a number of | ||||
| different interfaces that will enable you to parallelize things is almost no time at | ||||
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r1677 | all. A good place to start is the ``map`` method of our :class:`MultiEngineClient`. | ||
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| What is the best way to use MPI from Python? | ||||
| -------------------------------------------- | ||||
| What about all the other parallel computing packages in Python? | ||||
| --------------------------------------------------------------- | ||||
| Some of the unique characteristic of IPython are: | ||||
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r1677 | * IPython is the only architecture that abstracts out the notion of a | ||
| parallel computation in such a way that new models of parallel computing | ||||
| can be explored quickly and easily. If you don't like the models we | ||||
| provide, you can simply create your own using the capabilities we provide. | ||||
| * IPython is asynchronous from the ground up (we use `Twisted`_). | ||||
| * IPython's architecture is designed to avoid subtle problems | ||||
| that emerge because of Python's global interpreter lock (GIL). | ||||
| * While IPython's architecture is designed to support a wide range | ||||
| of novel parallel computing models, it is fully interoperable with | ||||
| traditional MPI applications. | ||||
| * IPython has been used and tested extensively on modern supercomputers. | ||||
| * IPython's networking layers are completely modular. Thus, is | ||||
| straightforward to replace our existing network protocols with | ||||
| high performance alternatives (ones based upon Myranet/Infiniband). | ||||
| * IPython is designed from the ground up to support collaborative | ||||
| parallel computing. This enables multiple users to actively develop | ||||
| and run the *same* parallel computation. | ||||
| * Interactivity is a central goal for us. While IPython does not have | ||||
| to be used interactivly, it can be. | ||||
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Brian E Granger
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r1256 | .. _Twisted: http://www.twistedmatrix.com | ||
| Why The IPython controller a bottleneck in my parallel calculation? | ||||
| ------------------------------------------------------------------- | ||||
| A golden rule in parallel computing is that you should only move data around if you | ||||
| absolutely need to. The main reason that the controller becomes a bottleneck is that | ||||
| too much data is being pushed and pulled to and from the engines. If your algorithm | ||||
| is structured in this way, you really should think about alternative ways of | ||||
| handling the data movement. Here are some ideas: | ||||
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r1677 | 1. Have the engines write data to files on the locals disks of the engines. | ||
| 2. Have the engines write data to files on a file system that is shared by | ||||
| the engines. | ||||
| 3. Have the engines write data to a database that is shared by the engines. | ||||
| 4. Simply keep data in the persistent memory of the engines and move the | ||||
| computation to the data (rather than the data to the computation). | ||||
| 5. See if you can pass data directly between engines using MPI. | ||||
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