# Understanding How Many Times Nested Loops Will Run

I am trying to understand how many times the statement "x = x + 1" is executed in the code below, as a function of "n":

``````for (i=1; i<=n; i++)
for (j=1; j<=i; j++)
for (k=1; k<=j; k++)
x = x + 1 ;
``````

If I am not wrong the first loop is executed n times, and the second one n(n+1)/2 times, but on the third loop I get lost. That is, I can count to see how many times it will be executed, but I can't seem to find the formula or explain it in mathematical terms.

Can you?

By the way this is not homework or anything. I just found on a book and thought it was an interesting concept to explore.

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Do you want to calculate exactly how many times it will execute, or are you just after the big-O estimate? –  Jon Sep 21 '11 at 13:34
I want the exact formula. Big-O estimate is straight forward I believe. –  DanielS Sep 21 '11 at 13:37

Consider the loop `for (i=1; i <= n; i++)`. It's trivial to see that this loops n times. We can draw this as:

``````* * * * *
``````

Now, when you have two nested loops like that, your inner loop will loop n(n+1)/2 times. Notice how this forms a triangle, and in fact, numbers of this form are known as triangular numbers.

``````* * * * *
* * * *
* * *
* *
*
``````

So if we extend this by another dimension, it would form a tetrahedron. Since I can't do 3D here, imagine each of these layered on top of each other.

``````* * * * *     * * * *     * * *     * *     *
* * * *       * * *       * *       *
* * *         * *         *
* *           *
*
``````

These are known as the tetrahedral numbers, which are produced by this formula:

``````n(n+1)(n+2)
-----------
6
``````

You should be able to confirm that this is indeed the case with a small test program.

If we notice that 6 = 3!, it's not too hard to see how this pattern generalizes to higher dimensions:

``````n(n+1)(n+2)...(n+r-1)
---------------------
r!
``````

Here, r is the number of nested loops.

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Great explanation, thanks a lot. –  DanielS Sep 21 '11 at 13:52

The mathematical formula is here.

It is O(n^3) complexity.

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That's it. Thanks a lot. –  DanielS Sep 21 '11 at 13:46

This number is equal to the number of triples {a,b,c} where a<=b<=c<=n.
Therefore it can be expressed as a Combination with repetitions.. In this case the total number of combinations with repetitions is: n(n+1)(n+2)/6

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The 3rd inner loop is the same as the 2nd inner loop, but your n is a formula instead.

So, if your outer loop is n times...

and your 2nd loop is `n(n+1)/2` times...

`(n(n+1)/2)((n(n+1)/2)+1)/2`

It's rather brute force and could definitely be simplified, but it's just algorithmic recursion.

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+1, but it needs some additional explanation. Writing down the formula and doing the substitutions would be nice. –  Jon Sep 21 '11 at 13:35
I noticed that, but how would you express that in a single formula? –  DanielS Sep 21 '11 at 13:35
I came up with that as well, but it doesn't seem to be right when you plug some sample numbers. For example, when n=3 that equation gives 21 right? But the answer should be 10. –  DanielS Sep 21 '11 at 13:43

1 + (1+2) + (1+ 2+ 3 ) +......+ (1+2+3+...n)

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You know how many times the second loop is executed so can replace the first two loops by a single one right? like

``````for(ij = 1; ij < (n*(n+1))/2; ij++)
for (k = 1; k <= ij; k++)
x = x + 1;
``````

Applying the same formula you used for the first one where 'n' is this time n(n+1)/2 you'll have ((n(n+1)/2)*(n(n+1)/2+1))/2 - times the x = x+1 is executed.

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T(T(n))? Do you think it's O(n^4) ? –  default locale Sep 21 '11 at 13:39
I came up with that as well, but it doesn't seem to be right when you plug some sample numbers. For example, when n=3 that equation gives 21 right? But the answer should be 10. Or am I missing something? –  DanielS Sep 21 '11 at 13:45
Obviously three nested loops give an asimptotical complexity of O(n^3). –  default locale Sep 21 '11 at 13:59
yeah, I didn't think it well, you must build from bottom up and not top down. hammar explained it very well –  Alin Sep 21 '11 at 14:12