Given your problem structure:
for(k=1;k<=n;k*=2) // <-- Takes 1+1/2+1/2^2+1/2^3...+1/2^n = O(log(n)) time
for(j=1;j<n;j++) // <-- Takes 1+2+3+...+n = O(n) time
The outer loop increments the value of k by
k*2, so you are basically half-ing the search space every time:
k = 1*2 = 2 => 1/2^1 time
k = 2*2 = 4 => above + 1/2^2 time
k = 4*2 = 8 => above + 1/2^3 time
k = 8*2 = 16 => above + 1/2^4 time
. . .
. . .
. . .
k = n*2 = 2^n => above + 1/2^n time
To put it another way, you are discarding half the elements every time. With that said, you are actually searching an array of size n in
1+(1/2)+(1/2^2)+(1/2^3)+...+(1/2^n) time = log(n) time
How did the
Take the analogy with binary tree in which at every node we are branching into two nodes which could be shown as a recurrence relation:
T(n) = 2T(n/2)
As the search space reduces by 2, as we go further from the root we must reach a boundary condition when the search space is equal to
1. The search space size at a depth of k would be
n/2^k (similar to what we saw above).
On equating the search spaces, our equation becomes:
n/2^k = 1
=> n = 2^k
Taking log on both sides:
=> log n = k log 2
=> log n/ log 2 = k
k = log n base 2.
So at the leaf node, the height of the binary tree that we would have traversed would be log(n) base 2. In our case we are diving the search space by two and traversing our search space in powers of two reaching the end element in
The overall time complexity of both the loops would be in the order of n * log n =