I've always taken it for granted that iterative search is the go-to method for finding maximum values in an unsorted list.

The thought came to me rather randomly, but in a nutshell: I believe I can accomplish the task in O(logn) time with n being the input array's size.

The approach piggy-backs on merge sort: divide and conquer.

Step 1: divide the findMax() task to two sub-tasks `findMax(leftHalf)`

and `findMax(rightHalf)`

. This division should be finished in `O(logn)`

time.

Step 2: merge the two maximum candidates back up. ~~Each layer in this step should take constant time ~~ This is so wrong. Each comparison is done in constant time, but there are `O(1)`

, and there are, per the previous step, `O(logn)`

such layers. So it should also be done in `O(1) * O(logn) = O(logn)`

time (pardon the abuse of notation).`2^j/2`

such comparisons to be done (2^j pairs of candidates at level j-th).

Thus, the whole task should be completed in `O(logn)`

time.`O(n)`

time.

However, when I try to time it, I get results that clearly reflect a linear `O(n)`

running time.

size = 100000000 max = 0 time = 556

size = 200000000 max = 0 time = 1087

size = 300000000 max = 0 time = 1648

size = 400000000 max = 0 time = 1990

size = 500000000 max = 0 time = 2190

size = 600000000 max = 0 time = 2788

size = 700000000 max = 0 time = 3586

How come?

Here's the code (I left the arrays uninitialized to save on pre-processing time, the method, as far as I'd tested it, accurately identifies the maximum value in unsorted arrays):

```
public static short findMax(short[] list) {
return findMax(list, 0, list.length);
}
public static short findMax(short[] list, int start, int end) {
if(end - start == 1) {
return list[start];
}
else {
short leftMax = findMax(list, start, start+(end-start)/2);
short rightMax = findMax(list, start+(end-start)/2, end);
return (leftMax <= rightMax) ? (rightMax) : (leftMax);
}
}
public static void main(String[] args) {
for(int j=1; j < 10; j++) {
int size = j*100000000; // 100mil to 900mil
short[] x = new short[size];
long start = System.currentTimeMillis();
int max = findMax(x);
long end = System.currentTimeMillis();
System.out.println("size = " + size + "\t\t\tmax = " + max + "\t\t\t time = " + (end - start));
System.out.println();
}
}
```