# Convex hull: known number of points but not points itself

I need to find an algorithm which computes a convex hull from a given set of points `S` of size `n`. I know that there are exactly 6 points from `S` which form the convex hull.

What is the best and most efficient way to compute this?

I thought about generating all possible combinations of points from `S` (which would be n choose 6 points) which would take O(n^6) and then check if this is a convex hull, which would take O(n) but lead into a very bad total runtime. There must be a better way. Any hints?

• as a side note, nC6 is O(n^6), not O(n) – user3235832 Jul 7 '16 at 9:12
• – Max Zuber Jul 7 '16 at 9:14
• How about first checking here en.wikipedia.org/wiki/Convex_hull_algorithms ? Edit: ninja'd – Vesper Jul 7 '16 at 9:15
• the convex hull is unique so why are you talking about 6 points etc just look up the algoritthm and execute it - its a minor problem if you have 1000 points or 10000 points it cannot be more than O(n^2) – gpasch Jul 7 '16 at 10:39
• Checking a 6-set takes O(N), so the total complexity would be O(N^7). Generally speaking, O(N^7) is just unthinkable, except for tiny N. For N=10, N^7 is already ten millions. For N=100, it is a hundred thousand billions. – Yves Daoust Jul 7 '16 at 18:52

If only 6 points lie on the convex hull then Jarvis March or the Gift-wrapping algorithm would be very efficient. It runs in `O(nh)` time where `h` is the number of points on the convex hull.
As already suggested, the Jarvis March / Gift-wrapping algorithm is very quick in this instance, because the time complexity is `O(nh)`, compared with `O(nlogn)` in Graham Scan.
The only algorithm that comes to thought that would be quicker would be Chan's algorithm that runs in `O(nlogh)`, but since `h` is very small the difference would be marginal. Read more about Chan's algorithm here.