# How to determine how often a statement in a nested loop is executed?

I am working through a section of a text on determining complexity of nested loops using recurrence relations. In this particular example I am trying to determine how many times the count variable will be incremented as a function of n.

This is the loop I am analyzing:

``````for (int i = 1; i <= n; i++) {
int j = n;
while (j > 0) {
count++;
j = j / 2;
}
}
``````

I think I understand that the first line would equate simply to n since it only executes for each value of n but it's the rest of it that I'm having trouble with. I think the answer would be something like n(n/2) except that this example is using integer division so I'm not sure how to represent that mathematically.

I've run through the loop by hand a few times on paper so I know that the count variable should equal 1, 4, 6, 12, 15, and 18 for n values of 1-6. I just can't seem to come up with the formula... Any help would be greatly appreciated!

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## 2 Answers

The loop executes for `n` in the range `[1, n]`. It divides by 2 each time for the `j` variable, which is set to n, so the number of time the inner loop executes is `floor(l2(n)) + 1,` where l2 is the binary log function. Add up all such values from 1 to n (multiply by `n`).

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+1 It would probably be a little bit clearer to express it as `floor(l2(i)) + 1` (j gets decremented each time through the inner loop; i controls the number of times the inner loop executes). –  Ted Hopp Nov 16 '12 at 2:39
Good catch, edited. –  jma127 Nov 16 '12 at 2:40
Actually, I take it back. It's not `floor(l2(i)) + 1` or `floor(l2(j)) + 1`. It's `floor(l2(n)) + 1`. The final answer is just `n` times that. –  Ted Hopp Nov 16 '12 at 2:42
Thank you for the help! So if I understand correctly my entire loop would be described by n((floor(l2(n)) + 1)? And just to refresh my memory as this is my first time through many of these concepts, floor here means the largest integer not greater than l2(n)? –  Stavrosnco Nov 16 '12 at 2:49
@Stavrosnco I just noticed that `j` is always defined as `n`. Therefore, Ted Hopp is correct. Sorry for any confusion. –  jma127 Nov 16 '12 at 3:04

The inner `j` loop adds the location of the first set bit to count.

Each divide by 2 is the same as a right shift until all the bits are zero.

So, 2 would be 10 in binary, and have a value of 2 for the inner loop. 4 would be 100 in binary, and have a value of 3 for the inner loop.

The outer loop seems to just multiply the location of the first set bit by the number itself.

Here is an example with n = 13.

13 in binary is 1101, so the first set bit is at location 4.

4 * 13 = 52. 52 is the final answer.

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