This is a toned down version of a computer vision problem I need to solve. Suppose you are given parameters n,q and have to count the number of ways of assigning integers 0..(q-1) to elements of n-by-n grid so that for each assignment the following are all true
- No two neighbors (horizontally or vertically) get the same value.
- Value at positions (i,j) is 0
- Value at position (k,l) is 0
Since (i,j,k,l) are not given, the output should be an array of evaluations above, one for every valid setting of (i,j,k,l)
A brute force approach is below. The goal is to get an efficient algorithm that works for q<=100 and for n<=18.
def tuples(n,q): return [[a,]+b for a in range(q) for b in tuples(n-1,q)] if n>1 else [[a] for a in range(q)] def isvalid(t,n): grid=[t[n*i:n*(i+1)] for i in range(n)]; for r in range(n): for c in range(n): v=grid[r][c] left=grid[r][c-1] if c>0 else -1 right=grid[r][c-1] if c<n-1 else -1 top=grid[r-1][c] if r > 0 else -1 bottom=grid[r+1][c] if r < n-1 else -1 if v==left or v==right or v==top or v==bottom: return False return True def count(n,q): result= for pos1 in range(n**2): for pos2 in range(n**2): total=0 for t in tuples(n**2,q): if t[pos1]==0 and t[pos2]==0 and isvalid(t,n): total+=1 result.append(total) return result assert count(2,2)==[1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1]
Update 11/11 I've also asked this on TopCoder forums, and their solution is the most efficient one I've seen so far (about 3 hours for n=10, any q, from author's estimate)