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Consider a two-dimensional grid (the usual lattice in the plane). For my purposes, a pattern or arrangement is an assignment of the numbers 1 and 2 to some connected subset of the grid points. For example, the following shows three separate arrangements:

.......1.....1....
.222...2.....12...
.111...2.....2....
.222...22...12211.
.......1....11.1..

I say that a small pattern matches a large one if the small one can be rotated or reflected such that all of its numbers are smaller than the numbers in the larger one. For example, consider this pattern:

......
.1212.
....2.
......

It does NOT match the leftmost arrangement above because it can't be rotated or reflected to fit in a 3x3 square. It DOES match the middle arrangement because it can be rotated and reflected to fit underneath. It does NOT, however, match the rightmost arrangement because however it is rotated or reflected to fit in the rightmost arrangement, the numbers are larger in the small pattern than the large arrangement. (If any of my examples are unclear or you need more information, just ask away in the comments area. Some clarifications in advance: the pattern can't be stretched, and it can't be rotated so it's diagonal with respect to the grid. That means there are four rotations and four reflections total, each of which can be translated.)

I am wondering about the following questions:

  1. How can I quickly test if a small pattern matches a large arrangement?

  2. Suppose I have a lot of small patterns. Can I pre-process them somehow to quickly tell if at least one of them matches an arrangement?

I suppose it'd be cool if a solution solves a more general problem (like arbitrary numbers -- not just 1 and 2 -- or allowing disconnected shapes), but I really only care about the case above. Thanks.

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Well you can check if none match by summing up the points in the arrangements. If the sum of a pattern is greater than the sum of the greatest arrangement there definitely isn't a match. I know this isn't what you asked, just throwing it out there. –  RedDeckWins Feb 11 '10 at 4:53
    
That's true and a good observation. (You can also count the number of 2s.) In my cases, I think that would settle very few of my pattern-matching queries. –  A. Rex Feb 11 '10 at 5:19

2 Answers 2

up vote 3 down vote accepted

2D convolution.
(complexity is n*Log(n) where n in number of elements) and might be good for larger matrices.

Make both matrices matching and non matching same size.

Test for each number seperatly. Example - cheking number k In serchung matrix (bigger) set numbers >= k on 0 other values on 1
In patteren matrix set values <= k on 1 other set on 0

Where the result of convolution is 0 is hit and match

Check for each rotation and reflexion (8 total)

That mean that general comlexity is k*n*log(n) where k is number of numbers (in your case 2) and n number of elements of bigger matrix)

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Great! I will upvote this in 5 hours. (My daily vote limit was reached.) Do you have any ideas for part 2? –  A. Rex Feb 11 '10 at 18:50

Here is an algorithm that does this without the added K (which is usually in the order of the size of the pattern). Instead it is O(n log sqrt(m)/m), where m is the size of the pattern.

http://cs.uef.fi/~fredriks/pub/papers/cpm02.pdf

In most applications, it is probably more than necessary.

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