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I know the following code has a complexity of O(log(n)):

while (n>1)
{
    counter++;
    n/=2;
}

I understand that here, n is being divided in half on each iteration, meaning that if n was 1000 then it will take ten rounds to get out of the loop. How did this lead to O(log(n))?

Sorry for the simple question, I really tried my best to get it before I asked.

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1  
What's the log base 2 of 1000? –  Paul Tomblin Mar 21 '11 at 17:11

5 Answers 5

up vote 6 down vote accepted

Each time through the loop, you divide by 2 (roughly; this will ignore rounding since it is an asymptotic argument). So if n = N at the start, after k iterations, n=N/(2^k). To arrive at n = 1, you have to satisfy 2^k = N. That is, k = log(N).

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Ah, thanks for all the answers, I guess this one sums it up. But another stupid question, why would n = (N/2^k) after k iterations. And would it be n=(N/3^k) if we were dividing by 3 rather than 2 and so on? –  xci13 Mar 21 '11 at 17:31
    
If dividing by 3, then, yes, after k iterations it would be N/(3^k). For any divisor d, if after k iterations you have N/(d^k), then on iteration (k+1) you will have (N/(d^k))/d = N/(d*(d^k)) = N/(d^(k+1)). That proves the general formula by induction, since on iteration 0 you have N = N/1 = N/(d^0). –  Ted Hopp Mar 21 '11 at 19:23
    
Ah, all clear now =D Thanks a lot! –  xci13 Mar 22 '11 at 16:47

The recurrence relation would be

 T(n) = T(n/2) + O(1)

Trying to solve it using Master's theorem will give the running time of T(n) as O(log n) (similar to what you get in Binary Search).

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Imagine that n is 2^x (e.g. 2^5=32, 2^10=1024 etc), so that the counter is incremented x times within the loop. By definition, x is a base 2 log n.

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By definition, logarithms aren't linear. In other words, they change by different amounts depending on the input. In your example, the first step takes n down by 500, while the fifth step reduces it by only 32. The closer you get to one, the slower n decreases. This "deceleration" is exactly the kind of behavior you get with a log.

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A simple hand-wavey explanation: What happens if you double n? Does the runtime double (that would be O(n))? No, the runtime increases by only one step. This is typical of O(log n).

[OTOH, if you squared n (say it increased from 4 to 16), then you find the number of steps double. Again, indicative of O(log n).]

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