Given your problem structure:

```
sum1=0;
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
sum++
```

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 **`log(n)`

come?

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
Rearranging:
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 *`log(n)`

time.

The overall time complexity of both the loops would be in the order of n * log n = `O(nlog(n))`

.

`n log n`

. It's difficult to understand your context. – Prince Feb 1 at 20:29