I came across this question in an interview. You have a nxn matrix containing 1s and 0s. You have to find the a row containing maximum number of 1s in most efficient way. I know it can be done in n^2 but is there any optimum solution for this ?
The optimal solution is O(n^2). Assume that the matrix contains only zeros. You have to inspect every cell to be sure of this. This is O(n^2). You could optimize the algorithm so that it stops searching if it finds a row that contains only 1s (this must be optimal) or if it has seen so many zeros in a row that it could not possibly beat the maximum seen so far. This could give a significant speedup in some cases, but it would still be O(n^2) in the general case. 


Here's the "most" efficient implementation in JavaScript. Like the above answers suggest; it short circuits if you hit a row with N 1's and continues the outer (row) loop if there is no possibility of the current row having a greater amount of 1's. But this answer also demonstrates efficiently using (read: placing) the conditional logic involved.



Worst case complexity will anyways be O( n^{2} ). But we can reduce the constant and general complexity. Calculate #1's in x For remaining nx rows, stop as and when we find that we are not in position to find bext answer from that row. Now the point is to obtain optimal value of x. PS: Analogous to  Select the best man out of 100, given the condition that you can choose only thrice. 


As an optimization: you parse the columns, calculate the MAX of 1 per row since now. After n/2 steps u start to eliminate those rows not suitable. 


m
, and the number of 1s you have found so far in the row you're checking isk
, and there are fewer thanmk
remaining columns to check, then bail out early since your current row clearly doesn't beat the best so far. There may also be stuff you can do with SIMD instructions, and parallelizing to take advantage of multiple cores. – Steve Jessop Jan 5 '12 at 12:09