m7thon's answer explains the problem with your solution, so I'll just explain how you can actually solve this . . .
The big thing to observe is that for any given tower, if you choose to increase its height from hi to hi + k, then you might as well increase the height of all shorter towers: that won't affect the maximum (because if hj < hi, then hj + k < hi + k), and may help by increasing the minimum. Conversely, if you choose to decrease the height of a tower from hi to hi − k, then you might as well decrease the heights of all taller towers.
So while there are 2n possible ways to choose which towers should be increased vs. decreased, we can actually ignore most of these. Some tower will be the tallest tower that we increase the height of; for all shorter towers, we will increase their height as well, and for all taller towers, we will decrease their height. So there are only n interesting ways to choose which towers should be increased vs. decreased: one for each tower's chance to be the tallest tower that we increase the height of.
[Pedantic note #1: You may notice that it's also valid to decrease the heights of all towers, in which case there's no such tower. But that's equivalent to increasing the heights of all towers — whether we add k to every height or subtract k from every height, either way we're not actually changing the max-minus-min.]
[Pedantic note #2: I've only mentioned "shorter towers" and "taller towers", but it's also possible that multiple towers have the same initial height. But this case isn't really important, because we might as well increase them all or decrease them all — there's no point increasing some and decreasing others. So the approach described here still works fine.]
So, let's start by sorting the original heights and numbering them in increasing order, so that h1 is the original height of the originally-shortest tower and hn is the original height of the originally-tallest tower.
For each i, try the possibility that the ith-shortest tower is the tallest tower that we increase the height of; that is, try the possibility that we increase h1 through hi and decrease hi+1 through hn. There are two groups of cases:
- If i < n, then the final height of the finally-shortest tower is min(h1 + k, hi+1 − k), and the final height of the finally-tallest tower is max(hi + k, hn − k). The final difference in this case is the latter minus the former.
- If i = n, then we've increased the heights of all towers equally, so the final difference is just hn − h1.
We then take the least difference from all n of these possibilities.
Here's a Java method that implements this (assuming int
-valued heights; note that hi is arr[i-1]
and hi+1 is arr[i]
):
private static int doIt(final int[] arr, final int k) {
java.util.Arrays.sort(arr);
final int n = arr.length;
int result = arr[n - 1] - arr[0];
for (int i = 1; i < n; ++i) {
final int min = Math.min(arr[0] + k, arr[i] - k);
final int max = Math.max(arr[n - 1] - k, arr[i - 1] + k);
result = Math.min(result, max - min);
}
return result;
}
Note that I've pulled the i = n case before the loop, for convenience.