Easy way to populate this matrix?

I would like to populate an `n * n` (n being odd) matrix in the following way:

``````_   _   _   23  22  21  20
_   _   24  10  9   8   37
_   25  11  3   2   19  36
26  12  4   1   7   18  35
27  13  5   6   17  34  _
28  14  15  16  33  _   _
29  30  31  32  _   _   _
``````

What is an easy way to do this using Mathematica?

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Can we assume that `n` is odd? – Szabolcs Nov 21 '11 at 9:31
@Szabolcs, I am sorry, you certainly can. – Mr.Wizard Nov 21 '11 at 10:39
Just curious: what are you going to use this for? – Sjoerd C. de Vries Nov 21 '11 at 16:22
@Sjoerd it relates to one of the Project Euler problems, but it is not the crux. I found the question of how to efficiently populate this construct an interesting question in itself. – Mr.Wizard Nov 21 '11 at 16:57

With this helper function:

``````Clear[makeSteps];
makeSteps[0] = {};
makeSteps[m_Integer?Positive] :=
Most@Flatten[
Table[#, {m}] & /@ {{-1, 0}, {-1, 1}, {0, 1}, {1, 0}, {1, -1}, {0, -1}}, 1];
``````

We can construct the matrix as

``````constructMatrix[n_Integer?OddQ] :=
Module[{cycles, positions},
cycles = (n+1)/2;
positions =
Flatten[FoldList[Plus, cycles + {#, -#}, makeSteps[#]] & /@
Range[0, cycles - 1], 1];
SparseArray[Reverse[positions, {2}] -> Range[Length[positions]]]];
``````

To get the matrix you described, use

``````constructMatrix[7] // MatrixForm
``````

The idea behind this is to examine the pattern that the positions of consecutive numbers 1.. follow. You can see that these form the cycles. The zeroth cycle is trivial - contains a number 1 at position `{0,0}` (if we count positions from the center). The next cycle is formed by taking the first number (2) at position `{1,-1}` and adding to it one by one the following steps: `{0, -1}, {-1, 0}, {-1, 1}, {0, 1}, {1, 0}` (as we move around the center). The second cycle is similar, but we have to start with `{2,-2}`, repeat each of the previous steps twice, and add the sixth step (going up), repeated only once: `{0, -1}`. The third cycle is analogous: start with `{3,-3}`, repeat all the steps 3 times, except `{0,-1}` which is repeated only twice. The auxiliary function `makeSteps` automates the process. In the main function then, we have to collect all positions together, and then add to them `{cycles, cycles}` since they were counted from the center, which has a position `{cycles,cycles}`. Finally, we construct the `SparseArray` out of these positions.

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@Mr.Wizard I added some explanation – Leonid Shifrin Nov 21 '11 at 11:19
Very nicely done. – Mr.Wizard Nov 21 '11 at 11:22
@Mr.Wizard One can remove double `Tranpose` and use `{cycles+#,cycles-#}&` instead of `{#,-#}&`, to make the code shorter, at the expense of some performance penalty. – Leonid Shifrin Nov 21 '11 at 11:24
How about `cycles+{#,-#}` ? :-) – Mr.Wizard Nov 21 '11 at 11:27
@Mr.Wizard Yes, perfect. I will edit. – Leonid Shifrin Nov 21 '11 at 11:27

I don't know the Mathematica syntax but I guess you could use an algorithm like this:

``````start in the middle of the matrix
enter a 1 into the middle
go up-right (y-1 / x+1)
set integer iter=1
set integer num=2
while cursor is in matrix repeat:
enter num in current field
increase num by 1
repeat iter times:
go left (x-1 / y)
enter num in current field
increase num by 1
repeat iter times:
go down-left (x-1 / y+1)
enter num in current field
increase num by 1
repeat iter times:
go down (x / y+1)
enter num in current field
increase num by 1
repeat iter times:
go right (x+1 / y)
enter num in current field
increase num by 1
repeat iter times:
go up-right (x+1 / y-1)
enter num in current field
increase num by 1
repeat iter-1 times:
go up (x / y-1)
enter num in current field
increase num by 1
go up-up-right (y-2 / x+1)
increase iter by 1
``````

you can also pretty easily convert this algorithm into a functional version or into a tail-recursion.

Well, you will have to check in the while loop if you aren't out of bounds as well. If n is odd then you can just count num up while:

``````m = floor(n/2)
num <= n*n - (m+m*m)
``````

I'm pretty sure that there's a simpler algorithm but that's the most intuitive one to me.

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While something like this certainly works, and it's straightforward, I think the point of the question is how to leverage Mathematica's built-in functionality and functional programming contstructs to come up with something easier and more compact :-) – Szabolcs Nov 21 '11 at 10:41
While I did my version independently, I just realized that this is the same algorithm I ended up with, just done procedurally. +1. – Leonid Shifrin Nov 21 '11 at 12:18
@Leonid I must admit that I got lost in the middle of reading this and thought "I'll just wait for a Mathematica answer." PeterT: +1 – Mr.Wizard Nov 21 '11 at 13:09

The magic numbers on the diagonal starting at 1 and going up right can be arrived at from

``````f[n_] := 2 Sum[2 m - 1, {m, 1, n}] + UnitStep[n - 3] Sum[2 m, {m, 1, n - 2}]

In  := f@Range@5
Out := {2, 8, 20, 38, 62}
``````

With this it should be easy to set up a `SparseArray`. I'll play around with it a bit and see how hard that is.

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You can reduce that to `2 - 3 n + 3 n^2` – Szabolcs Nov 21 '11 at 11:00
Even simpler is the recursive definiton `f[-1]=2;f[i_]:=6i+f[i-1];` – Timo Nov 21 '11 at 11:46
As usual oeis.org/… :) – Dr. belisarius Nov 21 '11 at 12:13
Going downwards by the big antidiagonal oeis.org/… – Dr. belisarius Nov 21 '11 at 12:31
@belisarius Or `FindSequenceFunction[{2, 8, 20, 38}]`, but that's not something easy to trust (are the following numbers going to match too?) – Szabolcs Nov 21 '11 at 13:15

First version:

``````i = 10;
a = b = c = Array[0 &, {2 (2 i + 1), 2 (2 i + 1)}];
f[n_] := 3*n*(n + 1) + 1;
k = f[i - 2];
p[i_Integer] :=
ToRules@Reduce[
-x + y < i - 1 && -x + y > -i + 1 &&
(2 i + 1 - x)^2 + (2 i + 1 - y)^2 <= 2 i i - 2 &&
3 i - 1 > x > i + 1 &&
3 i - 1 > y > i + 1, {x, y}, Integers];

((a[[Sequence @@ #]] = 1) & /@ ({x, y} /. {p[i]}));
((a[[Sequence @@ (# + {2, 2})]] = 0) & /@ ({x, y} /. {p[i - 1]}));

(b[[Sequence @@ #]] = k--)&/@((# + 2 i {1, 1}) &/@ (SortBy[(# - 2 i {1, 1}) &/@
Position[a, 1],
N@(Mod[-10^-9 - Pi/4 + ArcTan[Sequence @@ #], 2  Pi]) &]));
c = Table[b[[2 (2 i + 1) - j, k]], {j, 2 (2 i + 1) - 1},
{k, 2 (2 i + 1) - 1}];
MatrixPlot[c]
``````

Edit

A better one:

``````genMat[m_] := Module[{f, k, k1, i, n, a = {{1}}},
f[n_] := 3*n*(n + 1) + 1;
For[n = 1, n <= m, n++,
k1 = (f[n - 1] + (k = f[n]) + 2)/2 - 1;
For[i = 2, i <= n + 1, i++,  a[[i, 2n + 1]] = k--; a[[2-i+2 n, 1]] = k1--];
For[i = n + 2, i <= 2 n + 1, i++, a[[i, 3n+2-i]] = k--; a[[-i,i-n]] = k1--];
For[i = n, i >= 1, i--, a[[2n+1, i]] = k--;a[[1, -i + 2 n + 2]] = k1--];
];
Return@MatrixForm[a];
]

genMat[5]
``````
-
That looks quite interesting; would you please explain it? – Mr.Wizard Nov 23 '11 at 6:31
@Mr. The current code incarnation is still too convoluted. I'll clean it up and comment as soon as I get some free time. There are two main ideas there (nothing brillant) : 1) describe the "hexagon" geometrically and let Reduce[] find the edges and 2) Sort the edge elements by the angle subtended from the polygon center. The third idea is not mine f[n_] := 3*n*(n + 1) + 1 comes from here oeis.org/… – Dr. belisarius Nov 23 '11 at 6:40
I cannot imagine this being highly efficient, but +1 for a completely different approach. – Mr.Wizard Nov 23 '11 at 6:42
@Mr. I guess it will end up being quite efficient, as the geometric description is very simple once you draw it. Just look at my picture: 4 straight segments and two Pi/4 staircases. I'll remove the Reduce[] part. Then I will get rid of the SortBy[], because I'll build the edges in order, and I know the highest number is f[i-2]. So it will be three loops and O(n). – Dr. belisarius Nov 23 '11 at 6:52
@Mr. Then you can enjoy that now – Dr. belisarius Nov 24 '11 at 3:09

A partial solution, using image procssing:

``````Image /@ (Differences@(ImageData /@
NestList[
p = #, (HitMissTransform[p, #, Padding -> 0] & /@
{{{1}, {-1}},
{{-1}, {-1}, {1}},
{{1, -1, -1}},
{{-1, -1, 1}},
{{-1, -1, -1, -1}, {-1, -1, -1, -1}, {1, 1, -1, -1}},
{{-1, -1, -1,  1}, {-1, -1, -1, -1}, {-1, -1, -1, -1}}})] &, img, 4]))
``````

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Would this question be of interest to you? – abcd Nov 21 '11 at 20:18
@yoda Nice question and not easy at all. I think one should try to recognize rotated ellipses. – Dr. belisarius Nov 22 '11 at 1:26
It would be nice if you gave it a shot :) I can even bounty it to boost you up :D There's a few image processing questions floating around (here's another interesting one), but not enough people knowledgable to answer it. A lot of folks are just posting half-assed answers... – abcd Nov 22 '11 at 1:29
@yoda Posted a partial answer – Dr. belisarius Nov 22 '11 at 1:37
Thanks, @bel. I will keep my word on the bounty :) – abcd Nov 22 '11 at 1:39