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For each of the procedures below, let T (n) be the running time. Find the order of T (n) (i.e., find f(n) such that T (n) ∈ (f(n)).

Procedure BinarySearch(table T [a . . . b], int k):
 if a > b then
  return -1
 end if
 middle ← ⌊(a + b)/2⌋
 if T [middle] = k then
  return middle
 end if
 if k < T [middle] then
  return BinarySearch(T [a . . .middle], k)
 else
  return BinarySearch(T [middle . . . b], k)
 end if

I know how to find run times of simple functions but since this includes recursive calls so I'm having trouble.

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  • if you think about it a little bit, then you can intuitively deduce that it's O(log2(n)).
    – user529758
    Jan 23 '14 at 18:49
  • Lets say you have T( n ). Well for each T ( n ) , you split it in half. so T ( n / 2 ). How many times can you split n in half? see @H2CO3 's comment.
    – C.B.
    Jan 23 '14 at 18:50
  • You have a bug in your pseudocode. Let a=1 and b=2, and T[2]=k. Then middle=(a+b)/2=1 and k > T[1]. You will recursively call BinarySearch(T [1 ... 2], k). You should better change your pseudocode to "return BinarySearch(T [a . . .middle-1], k)" and "return BinarySearch(T [middle+1 . . . b], k)". As you have already checked T[middle], there is no sense in checking it again. Jan 24 '14 at 12:56
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This link (bottom of the page) depicts a very clear way of solving the recurrence relation of Binary Search algorithm.

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