# Merging Ranges In C++

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;
sort(ranges.begin(),ranges.end());
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 {
result.push_back(current);
current = *(it);
}
it++;
}
result.push_back(current);
``````
• 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. 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. 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(night_and_day);
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:

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. 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

O(n*log(n)+2n):

• 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`
• Just a little point: O(nlog(n) + 2n) = O(nlog(n) + n) = O(n*log(n)) Mar 11 '11 at 19:36
• of course. but (altho not in theory) such differences are significant in practice Mar 11 '11 at 20:00
• 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). 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). 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. 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;
sort(intervals.begin(),intervals.end(),cmp);
i=1,j=0;
while(i<intervals.size())
{
if(intervals[j].end>=intervals[i].start)  //if overlaps
{
intervals[j].end=max(intervals[i].end,intervals[j].end); //change
}
else
{
j++;
intervals[j]=intervals[i];  //update it on the same list
}
i++;
}
intervals.erase(intervals.begin()+j+1,intervals.end());
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)