6

I am attending a course online and stuck at the following question. What is the order of growth of the worst case running time of the following code fragment as a function of N?

int sum = 0;
for (int i = 1; i <= N*N; i++)
    for (int j = 1; j <= i; j++)
        for (int k = 1; k <= j; k++)
            sum++;

I thought that it is of the order of N^4 but it seems this answer is wrong. can you please explain?

4 Answers 4

6

It is of order O(N^6). You should note that it is not true that every loop simply add an order N to the complexity. Considering the following example:

int sum = 0;
for (int i = 1; i <= M; i++)
    for (int j = 1; j <= i; j++)
        for (int k = 1; k <= j; k++)
            sum++;

You should be able to figure out it is of order O(M^3) easily, so if you replace M=N^2, then you will get the answer. The key point is that every inner loop are of order O(N^2) in this case, but not O(N).

3

Let's denote n = N^2. Then, the loop will execute each time that k <= i <= j. This will be approximately n^3/6 times. Thus, the runtime is O(n^3)= O(N^6)


Explanation: Ignoring for a moment the cases where k==i or j==i or j==k, we take 1 out of 6 distinct triples :

 (a1,a2,a3)
 (a1,a3,a2)
 (a2,a1,a3)
 (a2,a3,a1)
 (a3,a2,a1)
 (a3,a1,a2)

Overall, there are n^3 triples. Only one out of 6 triples obeys the order.

2

One run of the inner loop increments sum exactly j times.

One run of the middle loop invokes the inner loop exactly i times, with values of j between 1 and i (inclusive). So it increments sum exactly 1+2+3+...i times, which is i.(i+1)/2 by the well-known "triangular numbers" formula.

The outer loop invokes the middle loop exactly N^2 times (let us denote it as M), with values of i between 1 and M (inclusive). So it increments sum exactly 1+3+6+...M.(M+1)/2 times. Similarly, this is M.(M+1).(M+2)/6, by the not-so-well-known "tetrahedral numbers" formula (http://en.wikipedia.org/wiki/Tetrahedral_number).

All in all, the final value of sum is N^2.(N^2+1).(N^2+2)/6.

Thinking in asymptotic terms, the inner loop is O(j), the middle one O(i^2) (by summation) and the outer one O(M^3) (by summation), i.e. O(N^6).

Also see Faulhaber's formula, which shows that the sum of n^k is O(N^(k+1)) (http://en.wikipedia.org/wiki/Faulhaber%27s_formula).

1

Any given run of the innermost (k) loop has a time proportional to j, but we've got to do one of those for each of j = 1 through j = i, and that sum 1 + 2 + … + i grows like i^2. So for any given i we've got an O(i^2) running time, but of course we've got to deal with i = 1 through i = N^2. The sum of i^2 for i = 1 through N^2 happens to grow like N^6.

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