# What is the Big O of a For Loop, Iterated Square Root Times?

I am trying to find the Big O for this code fragment:

``````for (j = 0; j < Math.pow(n,0.5); j++ ) {
/* some constant operations */
}
``````

Since the loop runs for √n times, I am assuming this for-loop is O(√n). However, I read online that √n = O(logn).

So is this for loop O(√n) or O(logn)?

Thanks!

• `√n = O(logn)` is just stupid. Where did you read this? Obviously the loop will run `O(sqrt(n))` times. – Niklas B. Jan 28 '14 at 1:44
• Where did you read that √n = O(logn)? Certainly, O(√n) != O(logn) since √n != log(n). Perhaps what was meant was that a certain algorithm to compute √n was O(logn) – Ted Hopp Jan 28 '14 at 1:44
• Please provide the link which says O(√n)=O(logn). In fact O(√n) > O(logn) for large n. – Matt Jan 28 '14 at 1:45
• So this for-loop just has O(√n)? – Jay Jan 28 '14 at 1:45
• Yes, assuming `j - 0` is a typo (should be `j = 0`) – Matt Jan 28 '14 at 1:46

One has to make several assumptions, but the time complexity of this loop appears to be O(√n). The assumptions are:

• the loop body executes in constant time regardless of the value of `j`.
• `j` is not modified in the loop body
• `n` is not modified in the loop body
• `Math.pow(n,0.5)` executes in constant time (probably true, but depends on the specific Java execution environment)

As a comment noted, this also assumes that the loop initialization is `j = 0` rather than `j - 0`.

Note that the loop would be much more efficient if it was rewritten:

``````double limit = Math.pow(n, 0.5);
for (j = 0; j < limit; j++ ) {
/* some constant operations */
}
``````

(This is a valid refactoring only if the body does not change `n`.)

• Can Java not do this kind of optimization itself?! – Niklas B. Jan 28 '14 at 2:05
• I would expect it to optimize this at least if `n` is a local variable, but maybe I'm wrong. – Niklas B. Jan 28 '14 at 2:09
• @NiklasB. - It's asking a lot of the compiler. Not only would it have to be able to establish that `n` did not change values (declaring it `final` would help), but the compiler would also have to know that `Math.pow(n,0.5)` returns the same value every time it is called with the same arguments. I don't think the compiler has such a detailed model available of the entire standard API. – Ted Hopp Jan 28 '14 at 2:11
• Yeah, everything would be better if the loop said `j * j < n` instead of `j < Math.pow(n, 0.5)`. Let the integers be integers and the floating point numbers be floating point. – Dawood says reinstate Monica Jan 28 '14 at 2:19
• @David: j * j < n would incur an integer multiply on each iteration; except for small n, it is advantageous to compute the integer square root once for all (unfortunately not available as such, must be emulated through floating-point sqrt). – Yves Daoust Jan 28 '14 at 9:23

Assuming the cost of the `pow` operation to be `O(P(n))` for some function `P`, the global cost of the loop is `O(√n.P(n))`. If the `pow` call is taken out of the loop and performed only once, the cost is expressed as `O(√n+P(n))`.

In case `P(n)=1`, this gives respectively `O(√n)` and `O(√n)`.

In case `P(n)=log(n)`, this gives `O(√n.log(n))` and `O(√n)`.

[The lower order term of the sum is absorbed by the other.]

The assumption `P(n)=log(n)` could be valid in the context of arbitrary precision integers, where the representation of an integer `n` requires at least `O(log(n))` bits. But that makes sense for huge values of `n` only.