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I have a very large table in mathematica ((dimcub-1)^3 elements) coming from an inverse FFT. I need to use periodic interpolation on this table. Since periodic interpolation requires that the first elements and last elements are equal, I create a new table of dim^3 elements manually and use that in my interpolation. It works but it is ugly/slow and due to my superfluous intermediate table, I hit the memory barrier sooner. Can any one tell me either how to turn my old table into a periodic one somehow by appending elements or use my non periodic table to make a periodic interpolation function? Here is my current piece of code:

mr 1 is the new table:

mr1 = Table[  0. , {i, 1, dimcub}, {j, 1, dimcub}, {k, 1, dimcub}];

Do[Do[  Do[   
      mr1[[m, n, k]] = oldtable[[m, n, k]] ;  , {m, 1, 
       dimcub - 1}]; , {n, 1, dimcub - 1}]; , {k, 1, dimcub - 1}]; 
Do[Do[     mr1[[m, n, dimcub]] =  mr1[[m, n, 1]]; 
  mr1[[m, dimcub, n]] =  mr1[[m, 1, n]];  
  mr1[[dimcub, m, n]] =  mr1[[1, m, n]];     , {m, 1, dimcub - 1}];  
 mr1[[n, dimcub, dimcub]] =  mr1[[n, 1, 1]]; 
 mr1[[dimcub, n, dimcub]] =  mr1[[1, n, 1]];  
 mr1[[dimcub, dimcub, n]] =  mr1[[1, 1, n]]; , {n, 1, dimcub - 1}]; 
mr1[[dimcub, dimcub, dimcub]] = mr1[[1, 1, 1]]; 


myinterpolatingfunction = 
 ListInterpolation[mr1, {{1, dimcub}, {1, dimcub}, {1, dimcub}}, 
  InterpolationOrder -> 1, 
  PeriodicInterpolation -> True];


myinterpolatingfunction takes much less memory and works perfectly once i remove the older tables. Any help will be greatly appreciated.

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4 Answers 4

Both Leonid's and Mr.Wizard's answers do too much work. In Leonid's case only the first three lines are necessary. To show this I'll change the last 4 Sets to Equals:

In[65]:= len = 4; oldtable = 
 Partition[Partition[Range[len^3], len], len]

Out[65]= {{{1, 2, 3, 4}, {5, 6, 7, 8}, {9, 10, 11, 12}, {13, 14, 15, 
   16}}, {{17, 18, 19, 20}, {21, 22, 23, 24}, {25, 26, 27, 28}, {29, 
   30, 31, 32}}, {{33, 34, 35, 36}, {37, 38, 39, 40}, {41, 42, 43, 
   44}, {45, 46, 47, 48}}, {{49, 50, 51, 52}, {53, 54, 55, 56}, {57, 
   58, 59, 60}, {61, 62, 63, 64}}}

In[66]:= oldtable[[All, All, -1]] = oldtable[[All, All, 1]];
oldtable[[All, -1, All]] = oldtable[[All, 1, All]];
oldtable[[-1, All, All]] = oldtable[[1, All, All]];
oldtable[[All, -1, -1]] == oldtable[[All, 1, 1]]
oldtable[[-1, All, -1]] == oldtable[[1, All, 1]]
oldtable[[-1, -1, All]] == oldtable[[1, 1, All]]
oldtable[[-1, -1, -1]] == oldtable[[1, 1, 1]]

Out[69]= True

Out[70]= True

Out[71]= True

Out[72]= True

What Leonid does is illustrated in the figures below. Lines 4-6 of his code do something as illustrated in the left-hand panel: copying a line (darker color) of a plane already copied (light colors). Line 7 is illustrated by the right-hand panel. This is a cell to cell copy of diagonally opposing positions, and its operation is not included in any of the first three copy actions separately, but is a result of their successive operation.

enter image description here

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Thanks for the illustration. I see your point and agree with you. The way Leonid does copying is left over from my original question in which I was creating a redundant copy of the table to increase the size by 1. Getting rid of the redundant intermediary table already saved me enough memory/time. –  Hsn Jun 1 '11 at 6:57
@Sjoerd +1 for the nice and visual analysis. –  Leonid Shifrin Jun 1 '11 at 9:05
+1 for plugging in your flag :) –  r.m. Jun 1 '11 at 20:46
@yoda +1 for noticing. Didn't think anyone would ;-) –  Sjoerd C. de Vries Jun 1 '11 at 20:54
@Sjoerd I didn't know you are from Serbia! en.wikipedia.org/wiki/File:Flag_of_Serbia_and_Montenegro.svg :) –  belisarius Jun 3 '11 at 0:17

You can get it much faster and more memory-efficiently by modifying the original table as follows:

oldtable[[All, All, -1]] = oldtable[[All, All, 1]];
oldtable[[All, -1, All]] = oldtable[[All, 1, All]];
oldtable[[-1, All, All]] = oldtable[[1, All, All]];
oldtable[[All, -1, -1]] = oldtable[[All, 1, 1]];
oldtable[[-1, All, -1]] = oldtable[[1, All, 1]];
oldtable[[-1, -1, All]] = oldtable[[1, 1, All]];
oldtable[[-1, -1, -1]] = oldtable[[1, 1, 1]];

These assignments replace nested loops and are much faster, plus you don't need memory to store the copy. This is based on an extended vectorized functionality of the Part command (array and general expression indexing), particularly vectorized assignments. It also matters to have your numerical array in a Packed array form, which is often the case.

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Leonid, you are burning up the charts this week. #78 on StackOverflow! –  Mr.Wizard Jun 1 '11 at 2:35
Some redundancy in there; see my answer/remark. –  Sjoerd C. de Vries Jun 1 '11 at 7:07
@Mr.Wizard Wow, did not expect that. Thanks for letting me know! But you forgot about @belisarius and @yoda, they are higher in that list. –  Leonid Shifrin Jun 1 '11 at 11:41
They also do not specialize in the mathematica tag. –  Mr.Wizard Jun 1 '11 at 11:53
@Mr.Wizard Can you clarify? They both have Mathematica tag listed below their avatars in that list (but have aslso other tags - is that what you mean?) –  Leonid Shifrin Jun 1 '11 at 11:57

Just because I'm a bit of a loon, Leonid's solution can be written as:

a = {0, 1}~Tuples~3~SortBy~Tr // Rest;

  (oldtable[[Sequence @@ #]] = oldtable[[Sequence @@ #2]]) &,
  {-a, a} /. 0 -> All
share|improve this answer
+1, less overall typing, so it is easier to extend. I'd give another +1, if I could, for the double Infix construction of a. –  rcollyer Jun 1 '11 at 3:08
Some redundancy in there; see my answer/remark. –  Sjoerd C. de Vries Jun 1 '11 at 7:08
+1. I wanted to show the closest corresppondence to the original loop-based solution, since it is easier to understand. Had in mind to add something very similar to what you did, but it was way too late :). Double infix is really nice indeed! But now, you are responsible for the explanation of how this works :). –  Leonid Shifrin Jun 1 '11 at 9:02
@Sjoerd Indeed, I agree. –  Leonid Shifrin Jun 1 '11 at 9:03
@rcollyer thanks! I use infix a lot, but I usually remove it form my posts because others rarely use it, so I figure it's hard to read. For me it is actually easier to read, because I know I am looking at a function with two arguments, and because it reads left-to-right in what I find is a logical way. –  Mr.Wizard Jun 1 '11 at 11:32
up vote 4 down vote accepted

Thanks for all the answers. I tried the suggestion by leonid but when I print my oldtable, it was still (dimcub -1)^3 dimensional. New elements were defined and I can see them individually but they do not show up as part of the oldtable when I print the whole table. So I ended up with something similar which is doing exactly what I needed:

oldtable= PadRight[oldtable, {dimcub, dimcub, dimcub}];
oldtable[[All, All, dimcub]] = oldtable[[All, All, 1]];
oldtable[[All, dimcub, All]] = oldtable[[All, 1, All]];
oldtable[[dimcub, All, All]] = oldtable[[1, All, All]];
oldtable[[All, dimcub, dimcub]] = oldtable[[All, 1, 1]];
oldtable[[dimcub, All, dimcub]] = oldtable[[1, All, 1]];
oldtable[[dimcub, dimcub, All]] = oldtable[[1, 1, All]];
oldtable[[dimcub, dimcub, dimcub]] = oldtable[[1, 1, 1]];

The answer by Wizard is far too advanced for my level of mathematica..

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I think we all missed the fact that you wanted the new table to be bigger than the old one. See my answer: What held for Leonid's answer also holds for yours: the last four lines are superfluous. –  Sjoerd C. de Vries Jun 1 '11 at 7:03
I wanted the new table bigger than the old one by 1 in each dimension since that is the only way I could have a table with matching end points to feed into periodic listinterpolation. If there is a way to do a periodic interpolation without this intermediate step, I would rather use it. –  Hsn Jun 1 '11 at 7:18
could you please modify your solution so as to make periodic only the 2nd and 3rd dimensions and not the 1st? [in my case the last 2 dimensions are spatial coordinates and the first one is time] –  Valerio Feb 6 '13 at 19:39

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