It's **not** gaussian here as it is a **geometric sequence** as you already mentioned.

The outer while loop will stop once j reaches n.

The number of iterations needed for that can be calculated by taking `log₂(n)`

as it is the question `2^x = n`

that is to solve here. (How many times do we have to keep multiplying by two until we reach n)

Interestingly enough this leads to:

```
log₂(n) log₂(n)
∑ 2^i = 2 - 1 = n - 1
0
```

`Sum from 1 to log2(n) taken over 2^i`

which is exactly `2^(log2n) - 1`

= `n - 1`

(restating the formula given above in case your fontset doesn't support the required unicode chars)

Using the fact here that

```
k k+1
∑ 2^i = 2 - 1
0
```

So the algorithm should be **O(n)**.

Alternatively you might calculate the sum with the **generic formula** for geometric sequences:

```
Sn = a0 * (1-q^n) / (1-q)
```

which should lead to the same result which in fact it does:

```
log₂n
1 - 2 1 - n
----------- = ------ = n - 1
1 - 2 -1
```