# Count number of overlapping intervals under memory constraints?

I need to maintain a list of intervals in the form of tuple (x, y) and answer queries which ask for the total number of intervals overlapping a point p. If there is no memory constraint i think the efficient solution would be to use a segment tree which requires O(nlogn) space by storing additional information in each node and using lazy update technique.

I tried to do it using an interval tree but the query's runtime depends on the number of reported intervals.

Can we do something better than this under memory constraints?

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Is the list of intervals dynamic ? Are you concerned with updates and deletions to/from it, or only queries ? Do you want to know which intervals a point lies in or only the number of intervals it lies in ? How many intervals are their likely to be ? Are their endpoints real numbers or integers ? –  High Performance Mark Nov 6 '10 at 10:53
@High Performance Mark Yes the list of intervals is dynamic, and updation and deletion takes place along with queries. I want only the number of intervals. The numbers of intervals may be large. The ends points are integers. –  trichromatica Nov 6 '10 at 10:57
large as in 10^6 or large as in 10^12 ? Are there any bounds on the end points of the range which includes all the intervals ? –  High Performance Mark Nov 6 '10 at 10:59
end points of range are 0 and ~ 10^10 –  trichromatica Nov 6 '10 at 11:00
@High Performance Mark It is large as in 10^6. Hmm, but i want a solution that does not depend on the number of reported intervals. –  trichromatica Nov 6 '10 at 11:08

A better solution is Fenwick Trees (also known as binary index trees), which have the restriction that you can either update a range and query a point or update a point and query a range. Since you update ranges and query a point a Fenwick Tree is a good solution.

They have O(log N) lookup and use O(N) space, where N is the range of x and y. Additionally updates are O(log N) too.

Best of all is they are trivial to code. Much more trivial than Segment Trees.

Here is a great tutorial: TopCoder - Binary Index Trees

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