# Efficient approach in the grid [closed]

Problem: we have to fill a 2D grid of size m*n with characters from the set S such that number of distinct sub-matrices in the resulting grid are close to a given number k.
This question is derived from http://www.codechef.com/JULY14/problems/GERALD09

Limits:
1<=n,m<16
1<=k <=m*n*m*n
|S|=4
time limit=0.1 sec

Assumption: Two sub-matrices are distinct if they are not having same dimensions or at least a pair of characters at their corresponding locations doesn't match.

My approach: We can start with a random grid and loop while acceptable solution is found and in each iteration, we can increase/decrease randomness depending on our current state(but we can stuck in local optimum states).

But the problem is that I don't know efficient way to calculate number of different sub-matrices in a sub-grid.I tried hashing for counting which is pretty fast ( O(n2m2)*cost of generating/searching a hash value for a sub-grid). But this approach doesn't give exact answers due to collisions of hash values and even after correcting it using the comment of @Vaughn Cato I can carry 15-25 iterations for optimum state finding and that is not enough .

Recently, I learned that Simulated annealing can be used to solve these kinds of problems.
http://www.theprojectspot.com/tutorial-post/simulated-annealing-algorithm-for-beginners/6
I am searching for any efficient approach for solving this optimization problem.

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## closed as off-topic by Andrew BarberNov 11 '14 at 18:48

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Wouldn't you just use the hash table to limit the number of possibilities? That is, you keep a table listing all the sub-matrices that have a particular hash value, then you just check each new entry for duplicates within the same list. – Vaughn Cato Jul 15 '14 at 13:37
thanks , but even after that I wouldn't be able find the close to optimal within the time limit .Actually, I was looking for other more efficient approaches. – cc2 Jul 15 '14 at 16:01
how can k be larger than mn? isn't it like that having smallest matrices with size of single character will result in maximum of mn distinct matrices? – rostok Jul 16 '14 at 13:17
@rostok , If we consider all distinct matrices of any dimension ,then we have mn different options for the top left corner and mn for diagonally opposite corner of any sub-matrix , thus giving at most mnm*n potentially distinct matrices in the worst case. – cc2 Jul 16 '14 at 15:05

I generated locally all possible numbers of sub matrices possible for particular `n` and `m`. For `n=m=3` I got only `11` out of `81` possibilities. For `n=3,m=4` I got only `19` out of possible `144` values. What's more, when I generated the values, I obtained all `19` possible options at the very beginning - after `263000` matrices out of possible `16M` I already had them. (I generated in the lexicographical order)
So, I assume, one possible solution might be to precompute as many as possible different values of `K` that can be achieved for given `n` and `m`, save either the seed for random generator or in some other way such that you need `O(1)` characters per `n-m-k` triplet, and for a particular test case just check two neighboring values - first `k` larger and smaller than given.
What's more, since number of possible `K` values is not large, it may be possible to generate them in other way: given all possible values of `K` for `nxm` table, along with the appropriate tables, we can only backtrack through the values in the next row, and try to obtain all possible matrices with all different values of `K` for `nx(m+1)`.