This is from an old Olympiad practice problem:
Imagine you have a 1000x1000 grid, in which the cell (i,j) contains the number i*j. (Rows and columns are numbered starting at 1.)
At each step, we build a new grid from the old one, in which each cell (i,j) contains the "neighborhood average" of (i,j) in the last grid. The "neighborhood average" is defined as the floor of the average values of the cell and its up to 8 neighbors. So for example if the 4 numbers in the corner of the grid were 1,2,5,7, in the next step the corner would be calculated as (1+2+5+7)/4 = 3.
Eventually we'll reach a point where all the numbers are the same and the grid doesn't change anymore. The goal is to figure out how many steps it takes to reach this point.
I tried simply simulating it but that doesn't work, because it seems that the answer is O(n^2) steps and each simulation step takes O(n^2) to process, resulting in O(n^4) which is too slow for n=1000.
Is there a faster way to do it?