## OR everything, NAND everything, AND both results

Finding all combinations in O(1) is obviously impossible. So the solution had to be something ad-hoc reformulation of the problem. **This is a complete intuition.** (I don't have proof, but it works).

I am not sure how to solve it mathematically using boolean algebra since it involves finding all combination pairs, but I'll try to explain it using Venn diagram.

The required area is exactly identical to Venn diagram of OR except for the area of AND. Therefore they have to be subtracted. If you try it with `n > 3`

, the picture would be even clearer.

The best way to test this method would be to simulate it with algorithms which don't have to be O(1). Anyways, you can try finding a direct proof. If you find it, please kindly share it with us too. :)

As far as your question goes, I'm sure you can implement it in O(1) yourself easily.

Good luck.