Connecting to and disconnecting from a continuously running kernel, on demand

Question

I realized that there are lots of advantages to driving C/C++/FORTRAN code directly from Mathematica as LibraryLink functions (instead of running them from the command line or a shell script, as I have usually done before). This will give access to a lot of functionality that is difficult or time consuming to implement in a low level language (example).

There are disadvantages too, mainly because the running environment is typically a remote server, and not a local workstation (i.e. I don't get a notebook GUI). So, to get around some of the disadvantages,

Is the following feasible to implement (see below)?

Can we have a Mathematica master kernel running a remote kernel, running parallel calculations in subkernels, and do the following:

While the calculation is running, connect to the master computer through MathLink from a laptop; check the state of the calculations, perhaps do some quick-to-compute preliminary analysis on the so far calculated results; make decisions about continuing the calculation or not; then disconnect. It should be possible to connect to and disconnect from the server as many times as necessary without aborting the calculations for good.

Do you think that such a thing is (theoretically) possible to implement with the current version of Mathematica? Or perhaps the current features are not general enough to allow it?

Before sitting down to study the documentation in detail and try to implement this, I was wondering if anyone is aware of any showstopper limitations (or if anyone has tried to implement it).

Answer 1

Why MathLink or webMathematica? (both quite time-consuming once you do something nontrivial)

Keep it simple:

On Windows: Use Remote Desktop to connect to your server (where you started the FrontEnd, starting the parallel calculation).

On Linux: Use TightVNC or NX or some such.

Answer 2

Instead of driving a remote kernel directly via MathLink, you should consider implementing this task with webMathematica:

• webMathematica 3 added support for queueing long running computations, which can also use compute kernels.
• you can connect to webMathematica's web frontend with a web browser to inspect the state of the running computation at any time.
• webMathematica already does all the handling of the kernel pool (launching and quitting kernels, re-launching crashed kernel, ...) which you would have to roll yourself.

Answer 3

Here is a stab at a basic mathlink solution.

In the kernel that contains status information define this post function:

post[e_] := Module[{link},
 Quiet[
  link = LinkConnect["status"];
  If[LinkReadyQ[link], LinkRead[link]; LinkWrite[link, e]];
  LinkClose[link]
 ]]

If there is nothing to connect (there is no open "status" link on the system) then this will just (quietly) fail.

Now define a check function on the kernel that wants to know about the status of e on the other kernel:

check[] := Module[{link, res},
 link = LinkCreate["status"];
 LinkWrite[link, "hi there"];
 res = LinkRead[link];
 LinkClose[link];
 res]

When called, this function creates the status link and ping the other kernel with a LinkWrite (which blocks). When the other kernel connects and reads the "hi there" string it will send its value of e and the checking function receives it and closed the link and returns the result.

On my system I defined two extra kernels, like so:

SetOptions[$FrontEnd, EvaluatorNames -> {
 "Local" -> {"AutoStartOnLaunch" -> True}, 
 "K1" -> {"AutoStartOnLaunch" -> False}, 
 "K2" -> {"AutoStartOnLaunch" -> False}}]

(be careful, this may wipe out other kernels you may have defined previously).

Then I made two notebooks, one with a K1 kernel and one with a K2 kernel, evaluating the check[] function in the K1 kernel and the post[] function in the K2 kernel.

Then in the posting K2 kernel I added a scheduled task, as follows:

i = 1;
RunScheduledTask[post[i++]]

Which posts the status of i every second (and also increments it once per second).

Then every time I run check[] in the checking K1 kernel I get the current value of i.

Answer 4

From rather superficial looking at the docs, I think what you ask for should be possible and even relatively easy to implement, but I'd choose J/Link and Java over Mathlink, for the following reasons:

• Java runtime is very stable. If you let it manage your remote kernels on the remote machine, you get a chance to have a better error / exception / crash handling. You can have a kernel pool as well, like WebMathematica does.

• Java is more high-level than C, and J/Link more high-level than MathLink. This can be a big deal since JLink hides quite a bit of low-level MathLink complexity from you, and you might not need that low-level layer for your purposes. From what I saw in the docs (I only used J/Link to call Java code from Mathematica before, so have no experience with the other side yet), it does have all the necessary functionality.

I have worked with both MathLink and JLink (from the Mathematica calling other program side only), and with all my love for C (which, as a language, I prefer to Java), my experience has been that you can usually get things up and running in Java much quicker. I attribute this to the excellent design of J/Link, which hides lots of underlying complexities of MathLink.

You will probably need to know or learn some rudimentary Java and learn to work with some good IDE like Eclipse or IntelliJ Idea, if you choose the Java route. Eclipse is preferred, because WorkBench basically is Eclipse with Mathematica support, and you can have JLink projects where you can even debug Mathematica and Java code at the same time (which is another strong plus for Mathematica / Java combination). But, learning either one is not difficult.

Answer 5

I'm optimistic that it's theoretically possible, but it looks like it'll require custom code. It seems to me that a good starting point is using LinkCreate and LinkConnect. I'm not quite enough of an expert on the notebook interface to think of a way to trick it into remoting all of its input to the kernel on the other side of such a link, but it's not hard to imagine writing a simple console mode program that's capable of connecting to the session in progress.