First: if (as mentioned) `0 <= i <= 1`

holds, the algorithm will never terminate.

So: Let `i > 1`

.

In every round of the loop the exponent of `i`

will be doubled. So in the `k`

-th round the number will be `i^(2^k)`

. The loop keeps going as long as `i^(2^k) < n`

holds, which is equivalent to `k < log log n`

. Exactly it is `log_2 log_i n`

, but due to all logarthms are equal exept for a constant factor, I just write `log log n`

. *Notice*: if `i`

is not constant, `1/log log i`

has to be multiplied to the complexity.

So the complexity of the algorithm is

`O(log log n)`

, if `someWork()`

is in `O(1)`

`O(n log log n)`

, if `someWork()`

is in `O(n)`

If `someWork()`

does `O(i^(2^k))`

operations in round `k`

you get a total complexity of

```
O( i + i^2 + i^(2^2) + i^(2^3) + ... + i^(2^(log log n)) )
```

This simplifys to `O(i * i^(2^(log log n)) ) = O(i * n)`

or `O(n)`

if `i`

is constant.

To see the simplification take a look at the following:

The number `i + i^2 + i^4 + i^8`

can be written in `i`

-ary as
`100 010 110`

. So you can see that

```
i + i^(2^1) + i^(2^2) + ... + i^(2^k) < i * i^(2^k)
```

holds, since it is equal to `100 010 110 < 1 000 000 000`

.

**Edit**:

I'm not sure what you mean by sigma notation but maybe it is this:

`i`

will always remain`0`

. – Don Roby Jul 4 '14 at 22:12