Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I was recently asked this question in an interview. Even though I was able to come up the O(n^2) solution, the interviewer was obsessed with an O(n) solution. I also checked few other solutions of O(nlog n) which I understood, but O(n) solution is still not my cup of tea which assumes appointments sorted by start-time.

Can anyone explain this?

Problem Statement:

You are given 'n' appointments. Each appointment contains a start time and an end time. You have to retun all conflicting appointments efficiently.

Person: 1,2,3,4,5 App St: 2,4,29,10,22 App End: 5,7,34,11,36

Answer: 2x1 5x3

O(nlog n) algorithm: separate start and end point like this:


then sort all of this points (for simplicity lets assume each point is unique):


it we have consecutive starts without ends then it is overlapping : 2s,4s are adjacent so overlapping is there

We will keep a count of "s" and each time we encounter it will +1, and when e is encountered we decrease count by 1.

share|improve this question
My gut says it is equivalent to sorting, but I do not see a proof for it yet, so I might be wrong. – amit Sep 5 '12 at 14:21
@Rotem: O(nlogn) solution is trivial using interval trees – amit Sep 5 '12 at 14:21
There is an easy O(n) solution if the appointments are sorted by the start time. Otherwise, it looks like O(n log n) – Andrey Sep 5 '12 at 14:22
It's impossible in O(n) in principle, because the output is not of size O(n). If all n appointments conflict then the output has size proportional to n^2. [Edit: actually I've made an assumption there about the output format that may not be warranted -- that it's a list of all pairs of conflicting appointments]. – Steve Jessop Sep 5 '12 at 14:27
@SteveJessop @Andrey: Correct, but to make it interesting - what about the binary problem? (Is there any collision?) Can it be be done in O(n)? Or is O(nlogn) optimal (assuming unsorted data) – amit Sep 5 '12 at 14:37
up vote 12 down vote accepted

The general solution to this problem is not possible in O(n).

At a minimum you need to sort by appointment start time, which requires O(n log n).

There is an O(n) solution if the list is already sorted. The algorithm basically involves checking whether the next appointment is overlapped by any previous ones. There is a bit of subtlety to this one as you actually need two pointers into the list as you run through it:

  • The current appointment being checked
  • The appointment with the latest end time encountered so far (which might not be the previous appointment)

O(n) solutions for the unsorted case could only exist if you have other constraints, e.g. a fixed number of appointment timeslots. If this was the case, then you can use HashSets to determine which appointment(s) cover each timeslot, algorithm roughly as follows:

  • Create a HashSet for each timeslot - O(1) since timeslot number is a fixed constant
  • For each appointment, store its ID number in HashSets of slot(s) that it covers - O(n) since updating a constant number of timeslots is O(1) for each appointment
  • Run through the slots, checking for overlaps - O(1) (or O(n) if you want to iterate over the overlapping appointments to return them as results)
share|improve this answer

Assuming you have some constraint on the start and end times, and on the resolution at which you do the scheduling, it seems like it would be fairly easy to turn each appointment into a bitmap of times it does/doesn't use, then do a counting sort (aka bucket sort) on the in-use slots. Since both of those are linear, the result should be linear (though if I'm thinking correctly, it should be linear on the number of time slots rather than the number of appointments).

At least if I asked this as an interview question, the main thing I'd be hoping for is the candidate to ask about those constraints (i.e., whether those constraints are allowed). Given the degree to which it's unrealistic to schedule appointments for 1000 years from now, or schedule to a precision of even a minute (not to mention something like a nanosecond), they strike me as reasonable constraints, but you should ask before assuming them.

share|improve this answer
In other words, "Use a bucket sort or radix sort or some other O(n) cheating sort algorithm"? Not an entirely satisfying solution :-) – Nemo Sep 5 '12 at 14:47
@Nemo: Not "cheating" at all -- simply selecting the right algorithm for the job. Whether you like it or not, I'd put pretty decent odds that it's the only way to meet the O(N) goal. – Jerry Coffin Sep 5 '12 at 14:49
I would not take that bet, but that is still a far cry from a proof. – Nemo Sep 5 '12 at 14:57
@Nemo: No, it's not a proof in itself -- but scheduling algorithms have been studied pretty heavily, and I don't see anything unusual enough about the specs here to indicate that the normal proofs don't apply. See, for example, the "charging argument", showing the optimal scheduling is based on the earliest finishing times (which obviously requires finding the earliest finishing times....) – Jerry Coffin Sep 5 '12 at 15:05
Fortunately I have a proof: consider the subset of this problem in which all appointments are of length 1 time unit (start and end times in the question are distinctly integral, so there's a quantim of time, but even if not consider the further subset in which appointments are length k and k-aligned). Then by solving it you solve the distinctness problem:, which is Theta(n log n) in the "algebraic decision tree" computation model. "Algebraic decision tree" is the formal way of saying, "no O(n) sorting tricks, you swine!" – Steve Jessop Sep 5 '12 at 15:06

A naive approach might be to build two parallel trees, one ordered by the beginning point, and one ordered by the ending point of each interval. This allows discarding half of each tree in O(log n) time, but the results must be merged, requiring O(n) time. This gives us queries in O(n + log n) = O(n).

share|improve this answer
But wouldn't building those trees take O(n log n) time each? – templatetypedef Sep 19 '12 at 4:45

This is the best I can think of, in horrible pseudocode. I attempted to reduce the problem as much as possible. This is only less than On^2 (I think).

Note that the output at the end will not show every appointment that a given appointment will conflict with on that appointment's specific output line...but at some point every conflict is displayed.

Also note that I renamed the appointments numerically in order of starting time.

output would be something like the following:

Appointment 1 conflicts with 2
Appointment 2 conflicts with
Appointment 3 conflicts with
Appointment 4 conflicts with 5
Appointment 5 conflicts with

appt{1},appt{2},appt{3} ,appt{4} ,appt{5}
  2      4       10       22      29
  5      7       11       36      34


for (i=1,i<=5,i++)
    list.shift()   **removes first element

for (i=1,i<=n,i++)
{   number=n
        {if (number>i)
            {if (appt(i).endtime() < appt(number).startime())
for (i=1,i<=n,i++)
    print "Appointment ",i," conflicts with:",appt{i}.conflictswith()  
share|improve this answer

I came across a Data Structure called Interval tree, with the help of which we can find intervals in less than O(n log (n)) time, depending upon the data provided

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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