You need a bit of math to see that. The inner loop iterates `Θ(1 + log [N/(i+1)])`

times (the `1 +`

is necessary since for `i >= N/2`

, `[N/(i+1)] = 1`

and the logarithm is 0, yet the loop iterates once). `j`

takes the values `(i+1)*2^k`

until it is at least as large as `N`

, and

```
(i+1)*2^k >= N <=> 2^k >= N/(i+1) <=> k >= log_2 (N/(i+1))
```

using mathematical division. So the update `j *= 2`

is called `ceiling(log_2 (N/(i+1)))`

times and the condition is checked `1 + ceiling(log_2 (N/(i+1)))`

times. Thus we can write the total work

```
N-1 N
∑ (1 + log (N/(i+1)) = N + N*log N - ∑ log j
i=0 j=1
= N + N*log N - log N!
```

Now, Stirling's formula tells us

```
log N! = N*log N - N + O(log N)
```

so we find the total work done is indeed `O(N)`

.

"It says"What says? Tell us whatever it is that you are assuming here. – dmckee Sep 5 '12 at 17:21