All the other answers are correct, I just want to amend the following.
I wanted to see, if the reduction of executions of the inner k-loop was sufficient to reduce the actual complexity below `O(n⁴).`

So I wrote the following:

```
for (int n = 1; n < 363; ++n) {
int sum = 0;
for(int i = 1; i < n; ++i) {
for(int j = 1; j < i * i; ++j) {
if(j % i == 0) {
for(int k = 0; k < j; ++k) {
sum++;
}
}
}
}
long cubic = (long) Math.pow(n, 3);
long hypCubic = (long) Math.pow(n, 4);
double relative = (double) (sum / (double) hypCubic);
System.out.println("n = " + n + ": iterations = " + sum +
", n³ = " + cubic + ", n⁴ = " + hypCubic + ", rel = " + relative);
}
```

After executing this, it becomes obvious, that the complexity is in fact `n⁴`

. The last lines of output look like this:

```
n = 356: iterations = 1989000035, n³ = 45118016, n⁴ = 16062013696, rel = 0.12383254507467704
n = 357: iterations = 2011495675, n³ = 45499293, n⁴ = 16243247601, rel = 0.12383580700180696
n = 358: iterations = 2034181597, n³ = 45882712, n⁴ = 16426010896, rel = 0.12383905075183874
n = 359: iterations = 2057058871, n³ = 46268279, n⁴ = 16610312161, rel = 0.12384227647628734
n = 360: iterations = 2080128570, n³ = 46656000, n⁴ = 16796160000, rel = 0.12384548432498857
n = 361: iterations = 2103391770, n³ = 47045881, n⁴ = 16983563041, rel = 0.12384867444612208
n = 362: iterations = 2126849550, n³ = 47437928, n⁴ = 17172529936, rel = 0.1238518469862343
```

What this shows is, that the actual relative difference between actual `n⁴`

and the complexity of this code segment is a factor asymptotic towards a value around `0.124...`

(actually 0.125). While it does not give us the exact value, we can deduce, the following:

Time complexity is `n⁴/8 ~ f(n)`

where `f`

is your function/method.

- The wikipedia-page on Big O notation states in the tables of 'Family of Bachmann–Landau notations' that the
`~`

defines the limit of the two operand sides is equal. Or:
f is equal to g asymptotically

(I chose 363 as excluded upper bound, because `n = 362`

is the last value for which we get a sensible result. After that, we exceed the long-space and the relative value becomes negative.)

User kaya3 figured out the following:

The asymptotic constant is exactly 1/8 = 0.125, by the way; here's the exact formula via Wolfram Alpha.

largefactors.Hint: The sum of numbers 1 to n is ((n+1)*n)/2Hint 2:`for (j = i; j < i *i; j += i)`

then you don't need the modulus test (because`j`

is guaranteed to be divisible by`i`

).`if`

statements areabsolutely notignored. This`if`

statement means the complexity is O(n^4) instead of O(n^5), because it causes the innermost loop to only execute`i`

times instead of`i*i`

times for each iteration of the second loop.`k < n^2`

part.So it is O(n^5) but knowledge (by understanding the`if`

) suggests O(n^4).5more comments