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.

`√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`j - 0`

is a typo (should be`j = 0`

) – Matt Jan 28 '14 at 1:46