# How to find max. and min. in array using minimum comparisons?

This is a interview question: given an array of integers find the max. and min. using minimum comparisons.

Obviously, I can loop over the array twice and use `~2n` comparisons in the worst case but I would like to do better.

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Well, I can imagine algorithms that need no comparisons at all (e.g. apply counting sort, then pick the first and last item). But I don't suppose that's the point. –  delnan Nov 24 '12 at 19:10

``````1. Pick 2 elements(a, b), compare them. (say a > b)
2. Update min by comparing (min, b)
3. Update max by comparing (max, a)
``````

This way you would do 3 comparisons for 2 elements, amounting to `3N/2` total comparisons for `N` elements.

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Trying to improve on the answer by srbh.kmr. Say we have the sequence:

``````A = [a1, a2, a3, a4, a5]
``````

Compare `a1` & `a2` and calculate `min12`, `max12`:

``````if (a1 > a2)
min12 = a2
max12 = a1
else
min12 = a1
max12 = a2
``````

Similarly calculate `min34`, `max34`. Since `a5` is alone, keep it as it is...

Now compare `min12` & `min34` and calculate `min14`, similarly calculate `max14`. Finally compare `min14` & `a5` to calculate `min15`. Similarly calculate `max15`.

Altogether it's only 6 comparisons!

This solution can be extended to an array of arbitrary length. Probably can be implemented by a similar approach to merge-sort (break the array in half and calculate `min` `max` for each half).

UPDATE: Here's the recursive code in C:

``````#include <stdio.h>

void minmax (int* a, int i, int j, int* min, int* max) {
int lmin, lmax, rmin, rmax, mid;
if (i == j) {
*min = a[i];
*max = a[j];
} else if (j == i + 1) {
if (a[i] > a[j]) {
*min = a[j];
*max = a[i];
} else {
*min = a[i];
*max = a[j];
}
} else {
mid = (i + j) / 2;
minmax(a, i, mid, &lmin, &lmax);
minmax(a, mid + 1, j, &rmin, &rmax);
*min = (lmin > rmin) ? rmin : lmin;
*max = (lmax > rmax) ? lmax : rmax;
}
}

void main () {
int a [] = {3, 4, 2, 6, 8, 1, 9, 12, 15, 11};
int min, max;
minmax (a, 0, 9, &min, &max);
printf ("Min : %d, Max: %d\n", min, max);
}
``````

Now I cannot make out the exact number of comparisons in terms of `N` (the number of elements in the array). But it's hard to see how one can go below this many comparisons.

UPDATE: We can work out the number of comparisons like below:

At the bottom of this tree of computations, we form pairs of integers from the original array. So we have `N / 2` leaf nodes. For each of these leaf nodes we do exactly 1 comparison.

By referring to the properties of a perfect-binary-tree, we have:

``````leaf nodes (L) = N / 2 // known
total nodes (n) = 2L - 1 = N - 1
internal nodes = n - L = N / 2 - 1
``````

For each internal node we do 2 comparisons. Therefore, we have `N - 2` comparisons. Along with the `N / 2` comparisons at the leaf nodes, we have `(3N / 2) - 2` total comparisons.

So, may be this is the solution srbh.kmr implied in his answer.

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It can be implemented with a divide-and-conquer strategy. –  Matthew Hall Nov 24 '12 at 23:14
+1 Nice analysis. Your tournament-like approach is I think just another way of looking at it. You could do it linearly also, just keep on comparing next 2 unprocessed pairs (a, b) and update the min, max as I explained in my answer. I think in both approaches comparisons made would be `3N/2-2` or `3N/2-3/2` depending on odd/even N. You could save extra recursion space if you go for a linear scan though ;) –  srbhkmr Nov 25 '12 at 4:04
See Knuth Volume 3, chapter 5.3.3, exercise 16. He says 3N/2 - 2 is the maximum. –  WaywiserTundish Nov 25 '12 at 6:51
@srbh.kmr: Indeed, I think the best is approach is to do a linear scan. For some reason it felt like I was "optimizing" on your answer but now it seems it is more of a pessimization... anyway, learned something new :) –  Asiri Rathnayake Nov 25 '12 at 16:03
@AsiriRathnayake: Quoting the referenced exercise: "(I. Pohl.) Show that we can find both the maximum and minimum of a set of n elements, using at most ceiling(3n/2) - 2 comparisons; and the latter number cannot be lowered." –  WaywiserTundish Nov 26 '12 at 5:04