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Suppose I have the following algorithm:

   if n == 1 then break
   R = generaterandom()

Now I understand that the complexity of this algorithm is log(n) but does it make log(n) calls to the random generator or log(n)-1 since it is not called for the call when n==1.

Sorry if this is obvious, but i've been looking around and its not really stated anywhere what the exact answer is.

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2 Answers 2

up vote 1 down vote accepted

There are ceil(log(n))calls to the generator

Proof Using induction:

There are ceil(log(k)) calls to generator for each k<n

log_2(1) = 0 => 0 calls

For arbitrary n>1 there is one call, and then from hypothesis ceil(log(n/2) more calls in the recursive calls.
This gives us total of ceil(log(n/2))+1 = ceil(log(n/2)) + log(2) = ceil(log(n/2 * 2)) = ceil(log(n)) calls


Note: In here, all logs are with base 2.

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But this is strange. For example: n=8, then we make calls to procedure for n=8,4,2,1. Generator is called 3 times. log(8) = 3 so ceil(log(n)) - 1 is not correct in this case. What am I doing wrong? –  Mythio Feb 22 '13 at 8:58
@Mythio Sorry for brainfart, log_2(1) = 0 (and not 1 as I previously states), move everything one down and the proof holds for log(n). Editted –  amit Feb 22 '13 at 9:08
Now it makes sense to me. Thanks for giving it in proof form. Really clarified it! –  Mythio Feb 22 '13 at 9:17

By the Master's Theorem, your method can be written as T(n) = T(n/2) + O(1), since you are dividing n into half every function call, and this is exactly O(log n). - I realized you are not asking for complexity analysis, but like I mentioned, the idea is the same (i.e. finding the number of calls is equivalent to its complexity)

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But the OP does not care about big O notation, he cares about the exact number of calls. –  amit Feb 22 '13 at 9:10
I realized that after I have posted, but the idea is the same, in another words, finding how many times a recursive function is called is equivalent to the complexity of the recursion. –  user1129335 Feb 22 '13 at 9:15

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