# Finding the computational complexity of an algorithm

Algorithm:

``````for (int i = 0; i < 2*n; i += 2)
for (int j = n; j >i; j--)
foo();
``````

I want to find the number of times foo() is called.

``````# of foo() calls for the second loop as i changes:

1st loop:   n - 0
2nd loop:   n - 2
3rd loop:   n - 4
nth loop:   n - f(x); f(x) = last term +2; where f(0) = 0

Total # calls = Summation(n - f(x)) from [i = 0] to [i = n/2 (where f(x) == n)]
= Summation(n) - summation(f(x))
= (n/2)(n+n)/2 - (n/2)(0 + n)/2
= n^2/2        - n^2/4
= n^2/4
``````

I've done all the work but my equation always gives values that are a bit off:

When n = 5: Recorded foo() calls is 9, but my equation gives 6.
When n = 6: Recorded foo() calls is 16, but my eqution gives 9.

What have I done wrong?

-
the algorithm makes sense, cant understand your results, please post code that doesn't work with the results you expect –  Jeremy Thompson Apr 15 '12 at 4:56

Sometimes an empirical approach works well. See http://codepad.org/zpBDNkuj.

``````#include <stdio.h>

int count(int n) {
int i, j, times = 0;
for (i = 0; i < 2 * n; i += 2)
for (j = n; j > i; j--)
times++;
return times;
}

int main() {
int i;
for (i = 0; i < 20; i++)
printf("%2d%10d\n", i, count(i));
return 0;
}

0         0
1         1
2         2
3         4
4         6
5         9
6        12
7        16
8        20
9        25
10        30
11        36
12        42
13        49
14        56
15        64
16        72
17        81
18        90
19       100
``````

Looking at the output, you can make inferences from how T(n) is generated from T(n-1), T(n-2), and so on, and you can compose a recursive definition of T. This appears to be the approach you have taken.

You might be able to get to a closed from faster by trying to figure out the pattern directly from the output. For example, we see from the output that:

• When n is odd, T(n) is ceil(n/2) ** 2
• When n is even, T(n) is (n/2) * (n/2+1)

This shows that T(n) converges asymptotically to n^2/4. This agrees with the answer you got. Perhaps you were saying your results were a "bit off" because for small values of n you were not seeing exactly n^2/4. This is fine. What matters is that in the limit the complexity is n^2/4. Of course, you can also just say THETA(n^2)....

-
Odd should be `(n+1)^2 / 4` and even should be `n/2 * (n/2 + 1)`. –  Mike Bantegui Apr 15 '12 at 5:14
what I did was make the function foo increment an "ActualCount" integer. Then I compared the ActualCount to the result generated by my complexity equation n^2/4. For the case of n= 5 the ActualCount was 9 while my equation came out to 6. –  Griffin Apr 15 '12 at 5:55
Ok; figured it out. Thanks for the alternate approach recommendation though, I'll see if I like that better =) –  Griffin Apr 15 '12 at 6:05