# Big O analysis for this for loop

`````` sum = 0;
for (i = 1; i <= n; i++) {    //#1
for (j = 1; j <= i * i; j++) {     //#2
if (j % i == 0) {    //#3
for (k = 1; k <= j; k++) {   //#4
sum++;
}
}
}
``````

}

The above got me confusing

``````Suppose #1 runs for N times
#2 runs for N^2 times
#3 runs for  N/c since for N inputs N/c could be true conditions
#4 runs for  N times
``````

Therefore roughly I could be looking at O(N^5) . I am not sure. Please help clarify.

EDIT I was wondering the runtime at the `if(j%i==0)`. Since it takes `N^2` inputs from its parent loop it could be doing `(N^2)/c` executions instead of `N/c`

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looks O(N^5) to me as well. but you shouldnt really consider #3 (the if itself, not the loop it contains) since it adds a 0.5 multiplier, which you shouldnt take into account for big-O stuff. so you get N times for #1, times N^2 for #2 times N^2 for #4 (multiplied by 0.5 which is ignored) –  radai Apr 9 '12 at 10:13
I see..So how come #4 has N^2 iterations according to your analysis? –  jmishra Apr 9 '12 at 10:16
I think `i` would be a factor of `j` much less often than half the time. –  sje397 Apr 9 '12 at 10:16
`(j%i==0)` is not checking whether numbers are even... –  Oliver Charlesworth Apr 9 '12 at 10:40
Oh yea, sorry I forgot about that. I thing putting `N/c` should be right thing to do –  jmishra Apr 9 '12 at 10:48

I would say its O(N^4) as its the same as.

`````` for (int i = 1; i <= n; i++)        //#1 O(n ...
for (int j = i; j <= i * i; j+=i) //#2 ... * n ...
for (int k = 1; k <= j; k++)    //#4 ... * n^2) as j ~= i^2
sum++;
``````

or

``````public static void main(String... args) {
int n = 9000;
System.out.println((double) f(n * 10) / f(n));
}

private static long f(long n) {
long sum = 0;
for (long i = 1; i <= n; i++)   //#1
for (long j = 1; j <= i; j++) //#2
sum += i * j; // # 4
return sum;
}
``````

prints

``````9996.667534360826
``````

which is pretty close to 10^4

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I see. So are you saying that #4 for loop executes N times instead of N^2? –  jmishra Apr 9 '12 at 10:53
+1 for the right answer. Although it can be proved mathematically rather than empirically (although that can be left as an exercise for the OP)... –  Oliver Charlesworth Apr 9 '12 at 10:57
I think the reduce in the first sample code make it relatively obvious. –  Peter Lawrey Apr 9 '12 at 10:58
+1, I am just performing so benchmarking as well and it indeed is `O(N^4)` –  Tomasz Nurkiewicz Apr 9 '12 at 10:59
Added an edit to show O(n^4) from the first example. –  Peter Lawrey Apr 9 '12 at 11:00

@PeterLawrey did the math, here are benchmarks plotted on chart (my data set - `n` vs. execution time in microseconds).

Basically I run the code in question several times with different `n` input (X-axis). Then I divided average execution time by `n^5`, `n^4` and `n^3` functions and plotted that:

Full size image

Note that this is a logarithmic scale and that all functions were scaled to more-or-less be in the same range.

Guess what, avergae execution time `t(n)` divided by `n^5` keeps getting decreasing, while `t(n)/n^3` keeps growing. Only `t(n)/n^4` is stabilizes when approaching infinity which proves that the average execution time is in fact `O(n^4)`.

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Hmm, this approach might work for simple examples like the OP's. But it shouldn't be recommended as a general approach; in a more complex example, the n^4 term may dominate until, say, n=1000000, and then a n^5 term might take over. The only way to be sure is to do the maths. –  Oliver Charlesworth Apr 9 '12 at 11:47
@OliCharlesworth: +1, actually I forgot to add it to my answer. As I said Peter did the math (transformation of an algorithm), this is just an empiric "prove". You are right, it won't work in some cases, but this one is simple enough - and looks cool IMHO ;-). –  Tomasz Nurkiewicz Apr 9 '12 at 11:54

I think the answer, using Sigma notation, would be like the following:

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