# SPOJ KRECT problem : Counting K-Rectangle [closed]

Here is spoj problem (krect) that states

Given a M*N square board. Each square contains a letter of the English alphabet ('A' .. 'Z').

A K-rectangle of the board is a rectangle whose sides are parallel to the sides of the board, and contains exactly K different types of letter

For example, with this 4*3 board:

CED
CEB
CBC
DDA

The rectangle [(1,1), (2,2)] is a 2-rectangle of the board because it contains 2 different letters: C and E.

Given M, N, K and the M*N board. Determine how many K-rectangles there are in the board.

Can you propose any solution? All ideas are wellcome

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## closed as not a real question by JDB, Andrew BarberMay 31 '13 at 12:43

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

The naive solution, checking every possible rectangle, requires you to look at 25502500 rectangles in the 100x100 case. You might be able to cut this down by noticing that a rectangle with more than K letters cannot be contained in a K-rectangle, and a rectangle with less than K letters cannnot contain a K-rectangle.

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The comments to the problem seem to indicate an O(n^4) solution would work just fine, so an outer loop over all top-left corners, and an inner loop over all widths and heights, would be sufficient. The trick is to scan the possible rectangle sizes efficiently, for example, if K=6, there's no point testing a rectangle of area less than 6. I'd suggest you keep a 2D array of rectangle sizes to scan, then scan it diagonally.

``````1 x .....6
2 x ..3
3 x .2
4 x .2
5 x .2
6 x 1
``````

If at any point you find a rectangle with more than K distinct symbols, you know no wider or taller rectangle is possibly a solution.

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This problem have a more efficient approach, though a bit difficult to implement:

1. Process th N*M rectangle that has its top left corner in the top left of the board (i.e., first row), save the number of all the letters into a "occurrence map", check the number of letters occurred;
2. "Roll" the rectangle to right for one column, then delete the leftmost column of letters from the "occurrence map", and add the rightmost column, check;
3. Do 1,2 for all the rows, check the first rectangle then roll through the row.

This has a worst case much less than 50*50*100(check every first rectangles) + 100*100*2(add/delete the elements) + 100*100*26(check the number of occurred letters) = 530 000 operations. Of course, the "first" rectangles can be generated from the top left rectangle using the same technique, which would reduce the worst case to 100*100 + 100*100*2 + 100*100*26 = 290 000 operations, but this would be harder to implement.

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There is a straightforward approach to this problem with time complexity O(a*n^3). Here a is the constant size of array of alphabets.

The solution:

From every square on the board (proceed order wise), you can create a rectangle. This will have a time complexity of O(n^3). Now for each rectangle update an array of alphabets. There is a bit of dynamic programming involved in here. You can update the array for a rectangle ending at square (j, k) by processing two arrays for rectangles ending at (j-1, k) and (j, k-1).

See the link given below if you have further doubts.