I am preparing for software development interviews, I always faced the problem in distinguishing the difference between O(logn) and O(nLogn). Can anyone explain me with some examples or share some resource with me. I don't have any code to show. I understand O(Logn) but I haven't understood O(nlogn).

It's the same as the difference between O(1) and O(n) or the difference between O(n) and O(n^2). – melpomene Apr 27 '19 at 0:48

Check out quora.com/HowareOlognandOnlogncalculated – B. Shefter Apr 27 '19 at 0:49

You still need to study a lot. O(..) describes the complexity of your algorithm. To be easy, you can imagine as the time to take to finish you algorithm for an n input, if O(n) it will finish in n seconds, O(logn) will finish in logn seconds and n*logn seconds for O(nlogn). O(1) means the cost of your algorithm is constant no matter how big n is. – Khoa Nguyen Apr 27 '19 at 0:54
Think of it as O(n*log(n))
, i.e. "doing log(n)
work n
times". For example, searching for an element in a sorted list of length n
is O(log(n))
. Searching for the element in n
different sorted lists, each of length n
is O(n*log(n))
.
Remember that O(n)
is defined relative to some real quantity n. This might be the size of a list, or the number of different elements in a collection. Therefore, every variable that appears inside O(...)
represents something interacting to increase the runtime. O(n*m)
could be written O(n_1 + n_2 + ... + n_m)
and represent the same thing: "doing n
, m
times".
Let's take a concrete example of this, mergesort
. For n
input elements: On the very last iteration of our sort, we have two halves of the input, each half size n/2
, and each half is sorted. All we have to do is merge them together, which takes n
operations. On the nexttolast iteration, we have twice as many pieces (4) each of size n/4
. For each of our two pairs of size n/4
, we merge the pair together, which takes n/2
operations for a pair (one for each element in the pair, just like before), i.e. n
operations for the two pairs.
From here, we can extrapolate that every level of our mergesort takes n
operations to merge. The bigO complexity is therefore n
times the number of levels. On the last level, the size of the chunks we're merging is n/2
. Before that, it's n/4
, before that n/8
, etc. all the way to size 1
. How many times must you divide n
by 2 to get 1
? log(n)
. So we have log(n)
levels. Therefore, our total runtime is O(n (work per level) * log(n) (number of levels))
, n
work log(n)
times.

Thank you for your answer. I have a follow up question for you. Can you prove that how time complexity of merge sort is O(nLogn)? Please don't use the master theorem while explaining the reasoning. Please share any resource which you think is useful. – Vagabond Apr 27 '19 at 18:46

You're welcome. I could do an outright proof, but it doesn't really belong in this question, and there are a million other proofs on Google. Instead, I'll add mergesort as an example in my question, and I think that will work to show you how to prove its runtime, as well. – MyStackRunnethOver Apr 28 '19 at 15:47

Yeah.. I think there is no need. I have got some of my basics right. I will work from here.. Thank you so much for helping me out. – Vagabond Apr 29 '19 at 18:27