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I have several 100x15 matrices; one of them is a distance. When elements of that matrix exceed a bound, I want to reset those elements to zero and also reset the corresponding elements of three other matrices to zero. Here's my silly way (but it works):

Do[ If[ xnow[[i, j]] > L, xnow[[i, j]] = 0.;
                  cellactvA[[i, j ]]  = 0.;
                  cellactvB[[i, j ]]  = 0.;
                  cellactvC[[i, j ]]  = 0.;   ], (* endIF  *)
   { i, 1, nstrips}, {j, 1, ncells}       ];  (* endDO *)

I tried ReplacePart:

 xnow = ReplacePart[ xnow, Position[ xnow, x_?(# > L &) ] ]

(something like this, I don't have it handy; it was done correctly enough to execute), but it was as slow as the loop and did not produce the correct replacement structure in matrix xnow. Please advise on how to do this in a way that is reasonably quick, as this calc is inside another loop (over time) that executes many many times. The overall calculation is of course, now, very slow. Thanks in advance.

Here is how I did this in R; very simple and quick:

    # -- find indices of cells outside window
indxoutRW  <- which( xnow > L, arr.ind=T )

    # -- reset cells outside window
cellrateA[indxoutRW] <- 0 
cellrateB[indxoutRW] <- 0 
cellrateC[indxoutRW] <- 0 

    # -- move reset cells back to left side
 xnow[indxoutRW]    <- xnow[indxoutRW] - L  
share|improve this question
Hello Bill. Your question is fine here. We also have a proposal for creating a mathematica specific site. Please consider committing to that to take it off the ground. – abcd Jan 4 '12 at 4:14
Not a complete answer but an observation. The slowness is due to the > check and I could not find any inbuilt function that performs that check faster than the pattern check _?(#>L&). I think most of the speedup of the suggested solutions can be attributed to improvements over using a Do loop from SpareseArray, MapThread. The inbuilt functions for < is Chop[xnow,L] which is about ten times faster. Ruebenko figured out that you can use mask = UnitStep[L - xnow] to create a mask and then just do xnow * mask. UnitStep is about fifty times faster than the Do loop (on a 1000x1000 matrix). – Timo Jan 4 '12 at 8:45
up vote 11 down vote accepted

How about this:

 matrixMask2 = UnitStep[limit - $xnow];
 xnow = $xnow*matrixMask2;
 cellactvA2 = $a*matrixMask2;
 cellactvB2 = $b*matrixMask2;
 cellactvC2 = $c*matrixMask2;

If you want to write fast code one thing to make sure is to check that On["Packing"] does not gives messages; or at least that you understand them and know that they are not an issue.

Edit for OP comment:

mask = UnitStep[limit - xnow];
{xnow*mask, cellactvA2*mask, cellactvB2*mask, cellactvC2*mask}

Hope this helps, you still need to set limit.

share|improve this answer
To get the xnow matric as well do xnow = $xnow*matrixMask2 – Timo Jan 4 '12 at 8:36
Thanks, added that. – user1054186 Jan 4 '12 at 8:40
I think you are the winner. This is about 50 times faster than the Do loop on a 1000x1000 matrix. – Timo Jan 4 '12 at 8:44
No, you should tests other stuff too - does it compile, or does the compiled form of the Do loop do well. How, does using N[UnitStep[..]] influence performance. This is just an idea of a direction. – user1054186 Jan 4 '12 at 8:50
Late last night I thought of matrixMask2 = Sign[Clip[limit - $xnow, {0, Infinity}]], but UnitStep (which I forgot about) is a third faster than that. – Brett Champion Jan 4 '12 at 16:40

The following will be based on SparseArrays, avoid extraneous stuff and very fast:

   HoldPattern[SparseArray[u___]]] := {u}[[4, 2, 2]];
positionExtr[x_List, n_] := 
     SparseArray[Unitize[x - n], Automatic, 1]]

replaceWithZero[mat_, flatZeroPositions_List, type : (Integer | Real) : Real] :=
  Module[{copy = Flatten@mat},
     copy[[flatZeroPositions]] = If[type === Integer, 0, 0.];
     Partition[copy, Last[Dimensions[mat]]]];

getFlatZeroDistancePositions[distanceMat_, lim_] :=
  With[{flat = Flatten[distanceMat]},
     With[{originalZPos = Flatten@ positionExtr[flat , 0]},
       If[originalZPos  === {}, #, Complement[#, originalZPos ]] &@
         Flatten@positionExtr[Clip[flat , {0, lim}, {0, 0}], 0]]];

Now, we generate our matrices, making sure that they are packed:

{xnow, cellactvA, cellactvB, cellactvC} = 
   Developer`ToPackedArray /@ RandomReal[10, {4, 100, 15}];

Here is the benchmark for doing this 1000 times:

  With[{L = 5},
    With[{flatzpos = getFlatZeroDistancePositions[xnow,L]},
       Map[replaceWithZero[#,flatzpos ]&,{xnow,cellactvA,cellactvB,cellactvC}]]

Out[78]= {0.203,Null}

Note that there was no unpacking in the process, but you have to ensure that you have your matrices packed from the start, and that you pick the correct type (Integer or Real) for the replaceWithZero function.

share|improve this answer
Very nice Leonid! The only thing bothering me is that to write such a solution in Mathematica takes too much time (maybe not for you, but you are a master of course). I think Mathematica should be as fast as R or Matlab out of the box, for loops. I.e. there should be more smart optimizations behind the scenes. Talk to TWJ or RG maybe ... – Rolf Mertig Jan 4 '12 at 10:11
@Rolf Thanks! I have the same feeling regarding loops. This is a hard task for Mathematica due to its symbolic nature though. I am sure it will get there eventually though. Note that Oliver's solution is still both faster and simpler than mine (something I did not expct for this problem, since I thought additional multiplications of unaffected elements in his solution would be more costly). – Leonid Shifrin Jan 4 '12 at 10:19
Leonid, I see you use extractPositionFromSparseArray rather than ["AdjacencyLists"]. Habit or deliberate? – Mr.Wizard Jan 13 '12 at 8:44

Yet another method which seems to be fast

xnow = $xnow; a = $a; b = $b; c = $c;
umask = Unitize@Map[If[# > limit, 0, #] &, xnow, {2}];
xnow = xnow*umask; a = a*umask; b = b*umask; c = c*umask;

Based on limited testing in Nasser's setup it seems it is as fast as the SparseArray-based mask.

Edit: Can combine with SparseArray to get a slight speed-up

umask2=SparseArray[Unitize@Map[If[# > limit, 0, #] &, xnow, {2}]];
xnow = xnow*umask2; a = a*umask2; b = b*umask2; c = c*umask2;

Edit 2: Inspired by ruebenko's solution, another built-in function (not nearly as fast as UnitStep but much faster than others):

umask3 = Clip[xnow, {limit, limit}, {1, 0}];
xnow = xnow*umask3; a = a*umask3; b = b*umask3; c = c*umask3;
share|improve this answer

Does this approach work for you?

matrixMask = 
 SparseArray[Thread[Position[xnow, _?(# > 0.75 &)] -> 0.], 
  Dimensions[xnow], 1.]; 
xnow = xnow * matrixMask;
cellactvA = cellactvA * matrixMask;
cellactvB = cellactvB * matrixMask;
cellactvC = cellactvC * matrixMask;

The basic idea is to create a matrix that is zero where your threshold is crossed, and one everywhere else. Then we use element-wise multiplication to zero out the appropriate elements in the various matrices.

share|improve this answer
Thanks, yes, that works, but is at least as slow as the original loop. (This is being executed about 2000 times....) – bill Jan 4 '12 at 5:40
@bill, please see my edit(1). I see that the SparseArray method is at least twice as fast as the loop method. I only tried it for 2,000 by 2,000 matrices. You can try for larger sizes, code is below. – Nasser Jan 4 '12 at 6:53

ReplacePart is notoriously slow.

MapThread should do what you want - note the third argument.

{xnow, cellactvA, cellactvB, cellactvC} = 
  RandomReal[{0, 1}, {4, 10, 5}]
L = 0.6;
MapThread[If[#1 > L, 0, #2] &, {xnow, xnow}, 2]

And for all four matrices

{xnow, cellactvA, cellactvB, cellactvC} =
 MapThread[Function[{x, y}, If[x > L, 0, y]], {xnow, #}, 
  2] & /@ {xnow, cellactvA, cellactvB, cellactvC}
share|improve this answer
Hi- I tried this and it doesn't work. I used the variable L where you have 0.6 above. It spits out some errors and grinds for a long time. (Tag Times Protected)....??? – bill Jan 4 '12 at 5:02
It works for me - did you define L? – Verbeia Jan 4 '12 at 5:05
Yes, it is defined earlier in the notebook. Do I need both MapThread statements or just the last one? I tried it both ways; I'll try it again. – bill Jan 4 '12 at 5:12
Just the last one. I showed both so that you could see what was going on - functional programming is quite unfamiliar if you have programmed in other languages. – Verbeia Jan 4 '12 at 5:14
Oh, I've just realised the issue -- the cell defining xnow etc should be in a separate cell to the MapThread command. I assumed you would realise this. If necessary, put a ; after the bit that says RandomReal[...]. Put each statement into a separate cell and you'll be fine. – Verbeia Jan 4 '12 at 5:17

may be

nRow = 5; nCol = 5;
With[{$nRow = nRow, $nCol = nCol},
  xnow = Table[RandomReal[{1, 3}], {$nRow}, {$nCol}];
  cellactvA = cellactvB = cellactvC = Table[Random[], {$nRow}, {$nCol}]
limit = 2.0;

now do the replacement

pos = Position[xnow, x_ /; x > limit]; 

{cellactvA, cellactvB, cellactvC} = 
  Map[ReplacePart[#, pos -> 0.] &, {cellactvA, cellactvB, cellactvC}];


Here is a quick speed comparing the 4 methods above, the LOOP, and then Brett, me, and Verbeia. May be someone can double check them. I used the same data for all. created random data once, then used it for each test. Same limit (called L) I used matrix size of 2,000 by 2,000.

So speed Timing numbers below does not include data allocation.

I run the tests once.

This is what I see:

For 2,000 by 2,000 matrices:

  1. Bill (loop): 16 seconds
  2. me (ReplacPart): 21 seconds
  3. Brett (SparseArray): 7.27 seconds
  4. Verbeia (MapThread): 32 seconds

For 3,000 by 3,000 matrices:

  1. Bill (loop): 37 seconds
  2. me (ReplacPart): 48 seconds
  3. Brett (SparseArray): 16 seconds
  4. Verbeia (MapThread): 79 seconds

So, it seems to be that SparseArray is the fastest. (but please check to make sure I did not break something)

code below:

data generation

nRow = 2000;
nCol = 2000;

With[{$nRow = nRow, $nCol = nCol},
  $xnow = Table[RandomReal[{1, 3}], {$nRow}, {$nCol}];
  $a = $b = $c = Table[Random[], {$nRow}, {$nCol}]

limit = 2.0;

ReplacePart test

xnow = $xnow;
a = $a;
b = $b;
c = $c;

  pos = Position[xnow, x_ /; x > limit];
  {xnow, a, b, c} = Map[ReplacePart[#, pos -> 0.] &, {xnow, a, b, c}]][[1]]

SparseArray test

xnow = $xnow;
a = $a;
b = $b;
c = $c;
  matrixMask = 
   SparseArray[Thread[Position[xnow, _?(# > limit &)] -> 0.], 
    Dimensions[xnow], 1.]; xnow = xnow*matrixMask;
  a = a*matrixMask;
  b = b*matrixMask;
  c = c*matrixMask

MapThread test

xnow = $xnow;
a = $a;
b = $b;
c = $c;
  {xnow, a, b, c} = 
   MapThread[Function[{x, y}, If[x > limit, 0, y]], {xnow, #}, 
      2] & /@ {xnow, a, b, c}

loop test

xnow = $xnow;
a = $a;
b = $b;
c = $c;
  Do[If[xnow[[i, j]] > limit,
    xnow[[i, j]] = 0.;
    a[[i, j]] = 0.;
    b[[i, j]] = 0.;
    c[[i, j]] = 0.
   {i, 1, nRow}, {j, 1, nCol}


There is something really bothering me with all of this. I do not understand how a loop can be faster that the specialized commands for this purpose?

I wrote a simple loop test in Matlab, like Bill had using R, and I getting much lower timings there also. I hope an expert can come up with a much faster method, because now I am not too happy with this.

For 3,000 by 3,000 matrix, I am getting

Elapsed time is 0.607026 seconds.

This is more than 20 times faster than the SparseArray method, and it is just a loop!

%test, on same machine, 4GB ram, timing uses cpu timing using tic/toc
%allocate data
nRow = 3000;
nCol = 3000;

%generate a random matrix of real values
%between 1 and 3
xnow = 1 + (3-1).*rand(nRow,nRow);

%allocate the other 3 matrices

%set limit


for i=1:nRow
    for j=1:nCol
        if xnow(i,j) > limit
            xnow(i,j) = 0;
            a(i,j) = 0;
            b(i,j) = 0;
            c(i,j) = 0;

fyi: using cputime() gives similar tic/toc.

share|improve this answer
Thanks, that worked, but was as slow as the original loop. – bill Jan 4 '12 at 4:42
I am still struggling just to find the correct commands to use. Once I master this part, I will then go on to the next phase, which is to filter out those that are slow :) – Nasser Jan 4 '12 at 4:46

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