# Maximum non-overlapping intervals in a interval tree

Given a list of intervals of time, I need to find the set of maximum non-overlapping intervals.

For example,

if we have the following intervals:

``````[0600, 0830], [0800, 0900], [0900, 1100], [0900, 1130],
[1030, 1400], [1230, 1400]
``````

Also it is given that time have to be in the range `[0000, 2400]`.

The maximum non-overlapping set of intervals is `[0600, 0830], [0900, 1130], [1230, 1400]`.

I understand that maximum set packing is NP-Complete. I want to confirm if my problem (with intervals containing only start and end time) is also NP-Complete.

And if so, is there a way to find an optimal solution in exponential time, but with smarter preprocessing and pruning data. Or if there is a relatively easy to implement fixed parameter tractable algorithm. I don't want to go for an approximation algorithm.

• Does "maximum" mean the largest number of intervals or the longest total duration of intervals? Your example solution is 3 intervals for a total duration of 6.5 hours. What makes it maximal, the 3 or the 6.5? – Adrian McCarthy Jul 11 '14 at 18:27

This is not a NP-Complete problem. I can think of an `O(n * log(n))` algorithm using dynamic programming to solve this problem.

Suppose we have n intervals. Suppose the given range is `S` (in your case, `S = [0000, 2400]`). Either suppose all intervals are within `S`, or eliminate all intervals not within `S` in linear time.

1. Pre-process:

• Sort all intervals by their begin points. Suppose we get an array `A[n]` of n intervals.
• This step takes `O(n * log(n))` time
• For all end points of intervals, find the index of the smallest begin point that follows after it. Suppose we get an array `Next[n]` of `n` integers.
• If such begin point does not exist for the end point of interval `i,` we may assign `n` to `Next[i]`.
• We can do this in `O(n * log(n))` time by enumerating n end points of all intervals, and use a binary search to find the answer. Maybe there exists linear approach to solve this, but it doesn't matter, because the previous step already take `O(n * log(n))` time.
2. DP:

• Suppose the maximum non-overlapping intervals in range `[A[i].begin, S.end]` is `f[i]`. Then `f[0]` is the answer we want.
• Also suppose `f[n] = 0`;
• State transition equation:
• `f[i] = max{f[i+1], 1 + f[Next[i]]}`
• It is quite obvious that the DP step take linear time.

The above solution is the one I come up with at the first glance of the problem. After that, I also think out a greedy approach which is simpler (but not faster in the sense of big O notation):

(With the same notation and assumptions as the DP approach above)

1. Pre-process: Sort all intervals by their end points. Suppose we get an array `B[n]` of n intervals.

2. Greedy:

``````int ans = 0, cursor = S.begin;
for(int i = 0; i < n; i++){
if(B[i].begin >= cursor){
ans++;
cursor = B[i].end;
}
}
``````

The above two solutions come out from my mind, but your problem is also referred as the activity selection problem, which can be found on Wikipedia http://en.wikipedia.org/wiki/Activity_selection_problem.

Also, Introduction to Algorithms discusses this problem in depth in 16.1.

• I'm a little confused on the second bullet of point 1. Are you saying we need to make a new array of the next possible interval? Is that what `Next[n]` is, or is `Next[n]==A[n]`? Perhaps you could write some more code to clarify? – David Grinberg Jan 10 '15 at 19:07