# Finding the dominating pairs in a set of coordinates in O(nlgn) [closed]

a coordinate a(xa,ya) dominates b(xb,yb) if ( xa>=xb and ya>=yb) how can I find all pairs in a set of coordinates in nlgn using divide and conquer?

-

## closed as off topic by Ether, interjay, sth, George Stocker♦, GravitonJun 29 '10 at 2:42

Questions on Stack Overflow are expected to relate to programming within the scope defined by the community. Consider editing the question or leaving comments for improvement if you believe the question can be reworded to fit within the scope. Read more about reopening questions here.If this question can be reworded to fit the rules in the help center, please edit the question.

I don't understand what you mean by 'all pairs'. Say you have three coordinates (x, y, and z) such that x dominates y and y dominates z. Is your answer ((x,y), (y,z), (x,z)) ? –  danben Jun 27 '10 at 2:34
Yeah you are right, I need to find all pairs using just nlgn –  ryanxu Jun 27 '10 at 2:36
See "Multidimensional Divide and Conquer" for a description and proposed algorithm to this problem, available at cs.uiuc.edu/class/fa05/cs473ug/hw/p214-bentley.pdf –  Richard Ye Oct 20 '13 at 2:53

Roughly speaking, any given vector (xa,ya) will dominate or be dominated by about half of the other vectors (ya,yb), because among the four cases for {xa <=> ya, xb <=>yb}, two are cases of dominance.

So we expect the solution to your problem to comprise about n*(n/2) pairs of vectors. The algorithm can't be cheaper than its solution, so n*ln(n) is not going to work.

-
This is what I found, but I dont quite understand it. sable.mcgill.ca/~nngman/comp507 especially "If we choose to sort all the points in their y-coordinates, then binary search can be used to identify all points in A that are dominated in just O(log N) time for each point in B. " –  ryanxu Jun 27 '10 at 3:03
@ryanxu: The page you linked to is about finding the number of points dominated by each point and able to solve range queries efficiently. What you said in the question is quite different. –  Aryabhatta Jun 27 '10 at 3:17
If I want to find the number of pairs, how would i do it in nlgn –  ryanxu Jun 27 '10 at 3:25
@ryanxu: Use the algorithm in the page you linked, and add up the values for each point. –  Aryabhatta Jun 27 '10 at 3:41
@Moron, is there a pseudo code for it? –  ryanxu Jun 27 '10 at 3:57

Do a quick sort where your comparison is first to sort by X then Y ( so you'd get something like 5,3 5,2 4,7 4,2 etc. Quicksort is nlogn

Then just iterate from the highest point down doing your compare. That would be at most O(n). You end up with O(n) + O(nlogn) => O(nlogn)

Quicksort uses divide and conquer - it divides on the pivot.

EDIT:

Another thing I considered. You can walk the entire set and put all the points that are dominated in the X coordinate by your point in a set. Then, walk that smaller subset and filter out the ones that are also dominated by your Y. This is just two walks, for O(n) performance.

-
That will find one pair in `O(n lg n)`, but he wants to find all pairs. –  danben Jun 27 '10 at 2:33
but to find all pairs this algorithm would take O(N^2) –  ryanxu Jun 27 '10 at 2:37
O(n logn) is quicksort average. Worst case is O(n^2), So I believe you can't sort here –  belisarius Jun 27 '10 at 3:07
You could instead use a different sorting algorithm like merge sort which is O(n log n) in both average and worst cases. (But quicksort is usually faster and you almost never end up with the worst case scenario.) –  Ben Alpert Jun 27 '10 at 3:11
You should a STABLE QuickSort. –  Fabio F. Jun 27 '10 at 9:12

lets say you have the points such that

a1 > a2 > a3 ... > an-1 > an d (read > as dominates) n is proporional to the number of points (N) in all situations.

the number of pairs itself is greater than nlogn (such as (A[1],A[2..n]) (A2], A[3..n]) ..A[n=1], A[n]) I think that is n (n-1) / 2.

so N logN doesn't seem to be possible

-

Assuming that you only need to count the number of pairs, you can take the sweeping approach:

1) Sort the points according to their X values

2) Collect the points into a search tree.

Here we use a balanced tree based on the Y values of the points. The tree should have a counter per internal node, indicating the number of items in the subtree rooted by it. These counters can be maintained without any impact on the time complexity of the tree operations. The usage of counters allows querying the number of items lower than a given value V, in logarithmic time.

More details of (2): we scan the points obtained in step (1) from left to right. For each point P traversed, we add P to the tree, and then compute the number of items with Y < P.Y. This number is added to the global count which is returned at the end.

Step (1) runs in N*Log(N) time, and step (2) performs N iterations of two Log(N) operations, therefore it has the same complexity.

-