Let

**L3** = log to the base 3
**L2** = Log to the base 2

Then the correct answer is **O(L3(L2(n))** and NOT O(L2(L2(n)).

Start with **x = x * 2**. x will increase exponentially till it reaches n, thus making the time complexity O(L2(n))

Now consider **x = x * x**. x increases faster than the above. In every iteration the value of x jumps to the square of its previous value. Doing some simple math, here is what we get:

For x = 2
n = 4, iterations taken = 1
n = 16, iterations taken = 2
n = 256, iterations taken = 3
n = 65536, iterations taken = 4

Thus, the time complexity is **O(L2(L2(n))**. You can verify this by putting values above values for n.

Now coming to your problem, **x = x * x * x**. This will increase even faster than x = x * x. Here is the table:

For x = 2
n = 8, iterations taken = 1
n = 512, iterations taken = 2
n = (512*512*512), iterations taken = 3 and so on

If you look at this carefully, this turns out to be **O(L3(L2(n))**. L2(n) will get you the power of two, but since you are taking cube of x in every iteration, you will have to take log to the base 3 of it to find out the correct number of iteration taken.

So I think the correct answer is **O(log-to-base-3(log-to-base-2(n))**

Generalizing this, if **x = x * x * x * x * .. (k times)**, then the time complexity is **O(log-to-base-k(log-to-base-2(n)**