I have a list of randomly ordered unique closed-end ranges R0...Rn-1 where

Ri = [r1i, r2i] (r1i <= r2i)

Subsequently some of the ranges overlap (partially or completely) and hence require merging.

My question is, what are the best-of-breed algorithms or techniques used for merging such ranges. Examples of such algorithms or links to libraries that perform such a merging operation would be great.


What you need to do is:

  1. Sort items lexicographically where range key is [r_start,r_end]

  2. Iterate the sorted list and check if current item overlaps with next. If it does extend current item to be r[i].start,r[i+1].end, and goto next item. If it doesn't overlap add current to result list and move to next item.

Here is sample code:

    vector<pair<int, int> > ranges;
    vector<pair<int, int> > result;
    vector<pair<int, int> >::iterator it = ranges.begin();
    pair<int,int> current = *(it)++;
    while (it != ranges.end()){
       if (current.second > it->first){ // you might want to change it to >=
           current.second = std::max(current.second, it->second); 
       } else {
           current = *(it);
  • 1
    Would the overall complexity of this approach be O(nlogn) {Essentially sort-complexity + 1 linear scan of N} ? Mar 11 '11 at 18:23
  • Depending on the size of the space the values fit in, it may be much more efficient to use a radix sort rather than quick sort. Radix sort is O(kn) where k is the size of the key space.
    – BeMasher
    May 11 '13 at 11:52
  • How does your algorithm handle cases, when the r[i].end + 1 == r[i+1].start? - Actually, this ranges can be merged too.
    – abyss.7
    Nov 10 '13 at 16:36

Boost.Icl might be of use for you.

The library offers a few templates that you may use in your situation:

  • interval_set — Implements a set as a set of intervals - merging adjoining intervals.
  • separate_interval_set — Implements a set as a set of intervals - leaving adjoining intervals separate
  • split_interval_set — implements a set as a set of intervals - on insertion overlapping intervals are split

There is an example for merging intervals with the library :

interval<Time>::type night_and_day(Time(monday,   20,00), Time(tuesday,  20,00));
interval<Time>::type day_and_night(Time(tuesday,   7,00), Time(wednesday, 7,00));
interval<Time>::type  next_morning(Time(wednesday, 7,00), Time(wednesday,10,00));
interval<Time>::type  next_evening(Time(wednesday,18,00), Time(wednesday,21,00));

// An interval set of type interval_set joins intervals that that overlap or touch each other.
interval_set<Time> joinedTimes;
joinedTimes.insert(day_and_night); //overlapping in 'day' [07:00, 20.00)
joinedTimes.insert(next_morning);  //touching
joinedTimes.insert(next_evening);  //disjoint

cout << "Joined times  :" << joinedTimes << endl;

and the output of this algorithm:

Joined times  :[mon:20:00,wed:10:00)[wed:18:00,wed:21:00)

And here about complexity of their algorithms:

Time Complexity of Addition


A simple algorithm would be:

  • Sort the ranges by starting values
  • Iterate over the ranges from beginning to end, and whenever you find a range that overlaps with the next one, merge them
  • Instead of sorting, could a std::priority_queue be used = sort of like sweep-line approach? Mar 11 '11 at 18:22
  • Since you just want to walk over them from lowest to biggest a std::priority_queue should work, but I don't think it would be faster/... than just sorting. After all you walk over all items in order, so you end up with them being sorted.
    – sth
    Mar 11 '11 at 18:29
  • @Rikardo a priority queue is only helpful when items arrive over time. If you have all of them, just sort them. Best-of-breed priority queue and sort are both O(nlogn) (priority queue is n insertions with O(logn) per insertion), but sort performs better and has less overhead.
    – Jim Balter
    Mar 12 '11 at 11:45
  • @JimBalter Could you please see my answer below and let me know your opinion? Jan 20 '20 at 19:22


  • Make a mapping of r1_i -> r2_i,
  • QuickSort upon the r1_i's,
  • go through the list to select for each r1_i-value the largest r2_i-value,
  • with that r2_i-value you can skip over all subsequent r1_i's that are smaller than r2_i
  • 1
    Just a little point: O(nlog(n) + 2n) = O(nlog(n) + n) = O(n*log(n))
    – andand
    Mar 11 '11 at 19:36
  • 3
    of course. but (altho not in theory) such differences are significant in practice Mar 11 '11 at 20:00
  • 1
    It's meaningless to say there's a difference in practice, because big-O is a theoretically defined notion and by its definition, O(nlogn+2n) = O(nlogn).
    – Jim Balter
    Mar 12 '11 at 11:29
  • Consider that quicksort is O(nlogn) but that could mean that its O(nlogn+40n) making your algorithm actually O(nlogn+42n) ... = O(nlogn).
    – Jim Balter
    Mar 12 '11 at 11:35
  • @Jim Balter: I agreed with andand that there is no difference in theory! And no it's not meaningless to say "there's a difference in practice". In practice practice is everything and big-oh's that make no difference in theory can totally ruin you! Mar 12 '11 at 14:34

jethro's answer contains an error. It should be

if (current.second > it->first){
    current.second = std::max(current.second, it->second);        
} else { 
  • This should have been an edit to jethro's answer rather than its own answer.
    – Brian
    Dec 29 '15 at 17:15

My algorithm does not use extra space and is lightweight as well. I have used 2-pointer approach. 'i' keeps increasing while 'j' keeps track of the current element being updated. Here is my code:

bool cmp(Interval a,Interval b)
     return a.start<=b.start;
vector<Interval> Solution::insert(vector<Interval> &intervals, Interval newInterval) {
    int i,j;
        if(intervals[j].end>=intervals[i].start)  //if overlaps
            intervals[j].end=max(intervals[i].end,intervals[j].end); //change
            intervals[j]=intervals[i];  //update it on the same list
    return intervals;

Interval can be a public class or structure with data members 'start' and 'end'. Happy coding :)


I know that this is a long time after the original accepted answer. But in c++11, we can now construct a priority_queue in the following manner`

priority_queue( const Compare& compare, const Container& cont )

in O(n) comparisons.

Please see https://en.cppreference.com/w/cpp/container/priority_queue/priority_queue for more details.

So we can create a priority_queue(min heap) of pairs in O(n) time. Get the lowest interval in O(1) and pop it in O(log(n)) time. So the overall time complexity is close to O(nlog(n) + 2n) = O(nlogn)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.