Can some body given a simple program or algorithm whose Time complexity is O(max(m,n)). I am trying to understand asymptotic notations. I followed some tutorials and understood what they have explained that i.e O(n), and O(n^2).

But now I want to understand Time complexity for O(max(m,n)) and how it is calculated. Please give a sample program or algorithm to demonstrate this.

  • 1
    What is max? Is it just the higher of m and n? If that's the case, then it is simply O(m) if m is larger than n, or O(n) if n is larger than m. Oct 18, 2013 at 17:47

4 Answers 4


A common theorem to prove when studying big-O notation for the first time is that

Θ(max{m, n}) = Θ(m + n)

In other words, any algorithm whose runtime is O(max{m, n}) also has runtime O(m + n), so any algorithm with this time complexity will fit the bill.

As a specific example of this, consider the Knuth-Morris-Pratt string-matching algorithm, which takes in two strings and returns whether the first string is a substring of the second. The runtime is Θ(m + n) = Θ(max{m, n}), meaning that the runtime is linear in the length of the longer of the two strings.

I apologize if this doesn't give something that intuitively has runtime max{m, n}, but mathematically this does work out.

Hope this helps!

  • 1
    @Gray Yep! Fixed. Good catch! Nov 3, 2016 at 19:43

The one I can think of is Python's izip_longest function :

Make an iterator that aggregates elements from each of the iterables. If the iterables are of uneven length, missing values are filled-in with fillvalue. Iteration continues until the longest iterable is exhausted.

For example:

In [1]: from itertools import zip_longest

In [2]: list(zip_longest([1, 2, 3, 4, 5, 6, 7], ['a', 'b', 'c']))
Out[2]: [(1, 'a'), (2, 'b'), (3, 'c'), (4, None), (5, None), (6, None), (7, None)]

In [3]: list(zip_longest([1, 2], ['a', 'b', 'c']))
Out[3]: [(1, 'a'), (2, 'b'), (None, 'c')]

In [4]: list(zip_longest([1, 2, 3], ['a', 'b', 'c']))
Out[4]: [(1, 'a'), (2, 'b'), (3, 'c')]

It should be clear why this is an O(max(m, n)) operation and not O(m+n), as far as I know; because when m > n, increasing n doesn't increase time required.

  • 1
    Actually Θ(m+n) is the same as Θ(max(m, n)) for reasonable definitions of Θ(...) for multiple variables. If one of n, m dominates the other, the usual reasoning for Θ(some sum) applies. And if n and m are roughly similar, both Θ(n+m) and Θ(max(n, m)) simplify to Θ(2n) (or Θ(2m), it's the same) which is again just Θ(n). That said, I've argued elsewhere that the version with the + is also educational.
    – user395760
    Oct 18, 2013 at 19:44

The simplest example is

for i=0 to max(m,n)
     print 'a'

From theory: O(max(m,n)) is just O(m+n)

The "real life" example of O(max(m,n)) may be the algorithm which for two unsorted arrays of size m and n respectively - finds the biggest elements of both

  • If O(max(m,n)) is just O(m+n), then why not just say O(m+n)? Oct 18, 2013 at 17:50
  • They might be emphasizing the max part. There are lots of ways to describe the order of a given function. Adding a non-zero constant doesn't change the order, for instance. Or the base of a log, or etc.
    – Joel
    Oct 18, 2013 at 17:52
  • 2
    @Robert as Joel said - the most probable reason is the will to emphasize that if we do the strict cost analysis, than it is actually the max operation, but in O notation it does not matter as max(m,n)=THETA (m+n) (these functions are equivalent in the complexity sense), this is an obvious consequence of 1/2(m+n) <= max(m,n) <= m+n <= 2*max(m.n)
    – lejlot
    Oct 18, 2013 at 17:59

I think that the best answer to your question is the Robert Harvey's comment. In my opinion, a good example of an algorithm where that kind of bounding is used is the DFS.

I hope, that this will clear your doubts:

DFS examines every vertex and every edge of a graph. Let n denotes the number of vertices in the graph and m denotes the number of edges in it.

Based on an above observation, you can derive an upper bound for the time complexity of DFS as O(max(n, m)).

Just notice, that there are graphs for which you cannot bound the time complexity of DFS by just O(n). A complete graph is an example.

Also, there are graphs for which you cannot bound the time complexity of DFS by just O(m). A null graph is an example.

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