# Difference between O(logn) and O(nlogn)

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
• – 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 next-to-last 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 big-O 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.