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Linda spaces is a very simple and clean protocol so why it has failed to garner as much popularity as MPI in the HPC universes?

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Linda tuple spaces, for those who don't know, is a distributed key-value pair model for distributed memory programming; the "sender" would publish a tuple, and the "receiver" would just query the distributed nosql database for the tuple, and the programmer wouldn't have to figure out from where to receive, or to where to send, and a lot of the semantics for waiting for messages, or what to do if the messages aren't ready, etc are simpler than MPI. In principle, over the time of a run the runtime could learn that (eg) certain sorts of tuples are typically generated by process A and queried by process B and cache the results over on process B's node as soon as they're generated.

For those who are in the HPC space, it may help to know that Gaussian is based on Linda tuple spaces.

And therein kind of lies the problem. Gaussian doesn't scale well. The tuple space model is so general that you can see how you'd implement a software-based distributed shared memory system on top of it; each process would publish each of its pages of memory with a key of (node, vmem page). And no one has figured out how to do distributed shared memory through software in a way that scales either. So this approach is just too hard to get the required performance out of. At the very least, you can see how the latencies of "messages" would be enormously increased with this model, as every time you want to get some new data you have to query a global, distributed database.(*)

So for HPC you get a poorly scaling middleware, but at least it's easier to use, right? I've heard that argument before, but I actually don't accept the premise. The vast majority of the time, the hard part about writing MPI code isn't figuring out what should go in the destination process argument for the MPI_Send call; the hard part is manually decomposing the problem by hand to the extent that you know what data needs to be transmitted, and what part your process is responsible for, and what parts you'll need to receive. That's the low-level, complicated part. Not having to fill in "source" and "destination" addresses doesn't normally simplify the complexity significantly for the HPC programmer, but it does put huge burdens on the middleware.

On the other hand, new programming languages like UPC or Chapel, with automatically and transparently distributed data structures, actually do reduce complexity by doing the decomposition for the programmer, or at least abstracting away the decomposition part to a separate part of the code from the operate-on-the-datastructure part. This is a significant win, and yet the lower levels of the code still know where sources and destinations are so you get good performance.

(*) Note that "scaling" and "performance" here are pretty broad terms: web services have indeed figured out how to make nosql databases scale out to enormous scales with acceptable performance for them. But they don't have the latency requirements, or the tighly coupled, fast-varying data in the tuples, that HPC users have. Different use cases have different requirements on data transports.

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Great comment! I might only add that one of the greatest strengths of MPI is that it is a standard, it's not an extension to the programming language (just a library with a runtime), and that it is relatively easy to implement. All that means that portable (in principle) applications could be written and that vendors could implement MPI as not so heavy wrapper on the existing communication infrastructure. That's why MPI is available virtually everywhere and its user base is so huge. –  Hristo Iliev May 14 '12 at 15:11
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