In sorted array, we can search in O(logn) by binary search. But I thought that in n*n array, how can we apply this algorithm(or other) to the array to search faster? n*n list is sorted each row and column like below.

  1  3  7 13 19
  2  5 12 14 20
  4  9 15 16 22
  8 10 18 23 25
 11 17 21 24 27

marked as duplicate by Dukeling algorithm Jan 2 '18 at 12:29

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  • use Divide and Conquer to find the element – Harsh Patel Jan 2 '18 at 12:06
  • "In sorted array, we can search in O(nlogn) by binary search" -> I think you mean O(log n) – SaiBot Jan 2 '18 at 12:11
  • How exactly is the 2D array sorted? – Henry Jan 2 '18 at 12:12
  • @Henry "each row is sorted, each column is sorted". – Weijun Zhou Jan 2 '18 at 12:13
  • @SaiBot I'm sorry. You're right. – jaeyong sung Jan 2 '18 at 12:15

Obviously the naive solution is to perform binary search on each row (or column) which will result in a runtime complexity of O (n log n).

The main problem I see in directly adapting binary search to the whole matrix is that there is no complete ordering. This makes it hard to define a "split element" where all elements to the "left" are smaller and all elements to the "right" are larger.

My approach for a direct adaptation would be closer to a spatial index like a quad-tree. The basic observation is the following: For each sub-matrix of the original matrix you can define bounds of the elements by looking at the top-left (lower bound) and bottom-right (upper-bound) element.

Now you can basically perform depth first search, recursively splitting the matrix in 4 sub matrices, computing upper and lower bounds for each sub matrix and discarding or exploring it depending if the key is within its bounds.

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