# What is the exact complexity of this program?

Someone give me this piece of code and I am suppose to find the exact complexity, or in other words to find a formula that for a specific n to know how to calculate L.

L = 0;
for (i = 1; i<n; i++)
for (j = 1; j<i; j++)
for (k = j; k<n; k++)
L++;

My first thoughts were (n^3 + n^2)/2, but are wrong.

For example n=5 L=20 ; n=10 L=240

Thanks :D

Edit: This problem is from Fundamentals of Algorithms, page 140 or slide 161 in pdf (this is a free book version) http://www.freebookspot.es/Comments.aspx?Element_ID=76025

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"I am suppose to find the exact complexity, or in oder words to find a formula that for a specific n to know how to calculate L." Those two things are not the same. See en.wikipedia.org/wiki/Big_O_notation, it explains big-theta too. –  Steve Jessop Feb 6 '13 at 17:33
Are you looking for the exact value of L, or for the big-theta approximation as the title says? –  interjay Feb 6 '13 at 17:34
Exact value of L. Sorry for confusion –  Alin Ciocan Feb 6 '13 at 17:41
@AlinC what is the actual problem ? When i = 1, L isn't touched; when i = 2, L is touched n - 1 times; when i = 3, L is touched n - 1 times + n - 2 times; and so on. Did you do this ? And you can't find a formula from that ? –  mmgp Feb 6 '13 at 17:47
L = i * j * k..? –  smk Feb 6 '13 at 17:50

## 2 Answers

Firstly: complexity is not about concrete numbers of n. It is about asymptotic behaviour. When one says that complexity of algorithm is O(f(n)), it doesn't mean that algorithm do strictly f(n) operations. In fact, it could do 2*f(n) or 1/2 * f(n) or f(n) + sqrt(f(n)). When talking about complexity one usually is interested in how fast number of operations grow with growth of input.

In your case you have to write 3 nested sums (one for each loop) and sum cost of inner operation (assume it's 1):

And this is exact formula (don't believe me — check using wolfram|alpha), but in complexity language it would be just O(n^3)

UPD: notice that this formula corresponds to the loops with condition of type less-or-equal rather than just less-than.

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Wouldn't the sums be up to n-1 and i-1 rather than n and i as the for loop conditions are < rather than <=? –  Ian Roberts Feb 6 '13 at 17:59
@IanRoberts, oh, really, I've missed that. n can be simply replaced by n-1, while i-1 instead of i isn't so simple. Thanks. Anyway, I think, correcting that inaccuracy isn't so hard to leave it to the reader as kind of a exercise :-) –  Barmaley.exe Feb 6 '13 at 18:02
Gratitude for your answer. :) –  Alin Ciocan Feb 6 '13 at 18:13

This is mathematics, not programming.

L is equal to (S is big-sigma, the sum):

n-1   i-1   n-1
S     S     S    1
i=1   j=1   k=j

n-1 i-1
= S   S  (n - j)
i=1 j=1

n-1 i-1      n-1 i-1
= S   S  n  -  S   S  j
i=1 j=1      i=1 j=1

n-1          n-1
= n * S   (i-1) -  S   (i-1)i/2
i=1          i=1

And so on. You need to know that the sum of the first n integers is n(n+1)/2 and that the sum of the first n squares is n(n+1)(2n+1)/6. You'll end up with a cubic equation in n.

Thanks to Barmaley's answer for pointing out that I'm not an undergraduate any more, I don't have to manipulate formulae to simplify them down. Wolfram Alpha will do it for me ;-)

The answer is n(n-1)(n-2)/3. Usually when these things factorize nicely, it turns out that there's a key insight (perhaps a geometrical one) that I could have made early on, to get the answer out without writing too many long expressions. This result looks suspiciously like the volume of a pyramid inscribed in a cuboid with sides n, n-1, n-2.

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When you sum 1 for k from j to n it is (n-j+1), not (n-j) (first time I lost this addend too) –  Barmaley.exe Feb 6 '13 at 18:00
@Barmaley.exe: oh of course, loop notation and sum notation don't match. Thanks. –  Steve Jessop Feb 6 '13 at 18:01
Thank you, I will do the sums by my self and I will post the answer. :) –  Alin Ciocan Feb 6 '13 at 18:10