Here's a perfect example of my problem:

Manipulate[Pause[n], {n, {1, 10}, ContinuousAction -> False}, SynchronousUpdating -> False]

It is illustrated by clicking 10 and then immediately clicking 1, that is, you shouldn't have to wait, it should stop pausing for ten seconds and begin pausing for only one second.

In general, Mathematica does not release a previous computation until the current one is finished. I need to override this in my application, which involves a computationally expensive function for only some values in the slider, and I want the computation to stop and restart when the mouse is dragged.

A Manipulate itself is not necessary for me, perhaps some trickery with Dynamics can achieve this? Also, would your solution work if the function that the slider drives is written with javalink?

  • $\begingroup$ Nice question. Of the top of my head I can think of a way for the particular "pause" case, but I'm sure that serves no purpose for you. Hummm $\endgroup$
    – Rojo
    Oct 15, 2012 at 16:50
  • $\begingroup$ @NasserM.Abbasi it's possible to make a pause controlled by another variable, that ends when you set it $\endgroup$
    – Rojo
    Oct 15, 2012 at 22:37

1 Answer 1


Ok, I still hope for a solution to the more general question on how to abort and relaunch a main link evaluation from the preemtpive link. But I'll offer a simple solution to the problem at hand. It just demonstrates how you can use a flag to stop your computation.

timings[t_] = PDF[NormalDistribution[1/2, 1/10]][t];

SetAttributes[myComputation, HoldFirst];
myComputation[x_] := Identity@With[{xval = x},
    If[x =!= xval, 
     Return[xval, myComputation]], {Round[timings[x]/0.05]}]; x

Dynamic[myComputation[x], SynchronousUpdating -> False]
Plot[timings[t], {t, 0, 1}]

or Slider[Dynamic[x], ContinuousAction -> False] if you prefer.

I assumed that your Pause was there to represent a particular computation and not a real pause. If that was not the case please say.


I'm writing this here because the comments are not enough, hope you don't mind! So here's a computation that takes a varying amount of time:

AbsoluteTiming[Total@Table[i^4, {i, 10}]]
{0.000062, 25333}

AbsoluteTiming[Total@Table[i^4, {i, 10000000}]]
{19.341138, 20000005000000333333333333333000000}

When I drag the slider all the way to the right and let go and then immediately drag it all the way back to the left I shouldn't have to wait the whole 19 seconds. But I don't see how your code fixes this....

SetAttributes[myComputation, HoldFirst];
myComputation[x_] := Identity@With[{xval = x},
   If[x =!= xval, Return[xval, myComputation]];
   Total@Table[i^4, {i, x}]]
{Slider[Dynamic[x], {10, 10000000}], Dynamic@x, 
 Dynamic[myComputation[x], SynchronousUpdating -> False]}
  • $\begingroup$ Ok, this looks good, can you use my original example with the function: f[x_] := Total@Table[i^4, {i, x}] $\endgroup$
    – M.R.
    Oct 15, 2012 at 22:04
  • $\begingroup$ @M.R. and what would x be, your example's n? In any case that example should get evaluated in no time $\endgroup$
    – Rojo
    Oct 15, 2012 at 22:35
  • $\begingroup$ @M.R. You should look at Sum -- it is likely better than Total@Table[...] for your application. $\endgroup$
    – Mr.Wizard
    Oct 15, 2012 at 22:53
  • $\begingroup$ @Mr.Wizard lol! For once, I was actually trying to have a SLOWER function to test this on... $\endgroup$
    – M.R.
    Oct 16, 2012 at 14:54

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