I have a two-dimensional array of objects. Each object has, at all times, some (variable) score (i.e. an object's score at time t is not necessarily the object's score at time t+1). I want to find the most efficient algorithm which will duplicate any object with a greater score than its neighbour, and place that duplicate into the neighbour's place.^{1}

My first impulse was the naive solution:

- Create a copy of the array
- set "changeWasMade" flag to false
- cycle through all positions p
- compare scores with all neighbours n
- if score(p) > score(n), replace n in the copied grid with a copy of p and set "changeWasMade" to true

- if "changeWasMade", then discard original grid, and repeat using the copy as the new original; else, return the copy

However, for an n x n array, this seems to be O(n^{4}) (n^{2} possible iterations of n^{2} checks), which seems pretty slow to me. Since my algorithmic knowledge is pretty poor, I thought it would be wise to ask if there's a quicker way to do this.

*UPDATE*

It's just occurred to me that it might be quicker to make one "pass" of replacements, and then to check that all newly created (i.e. cloned) objects have the highest score of their neighbours (i.e. are a local maximum). If they are, great, the right thing has happened - if they're not, then replace them with a copy of the neighbour with the highest score. This will probably cut down on required iterations (though it will require some good book-keeping to keep everything straight!) - is there still a quicker method?

** Footnotes**

- (For some context, for those who have read "The Quantum Thief", this is the setup of the prison described in the opening pages)

`"repeat using the copy as the new original"`

- I'm wondering about this part. So your algorithm keeps repeating until no changes are made any more? Do you mean repetition and all takes O(n^4) or the part you are repeating takes that long (if the latter case, I then presume you only run the algorithm once at each time step)? In the prior case, all objects will surely end up being the same. – Dukeling May 21 '13 at 14:17`O(n)`

then entire process would be`O(n^2)`

overall. If you interested in the literal algorithm you described, does the "winner" flood the 4 direction neighbors or the 8 (meaning the diagonals included)? Would you flood the localized winners or the overall ones? – SGM1 May 21 '13 at 14:32