## Concept

Suppose we had an array of `bool`

representing which numbers so far haven't been found (by way of summing).

For each number `n`

we encounter in the **ordered** (increasing values) subset of `S`

, we do the following:

- For each existing
`True`

value at position `i`

in `numbers`

, we set `numbers[i + n]`

to `True`

- We set
`numbers[n]`

to `True`

With this sort of a sieve, we would mark all the *found* numbers as `True`

, and iterating through the array when the algorithm finishes would find us the minimum unobtainable sum.

## Refinement

Obviously, we can't have a solution like this because the array would have to be infinite in order to work for all sets of numbers.

The concept could be improved by making a few observations. With an input of `1, 1, 3`

, the array becomes (in sequence):

^{(numbers represent true values) }

An important observation can be made:

- (3) For each next number, if the previous numbers had already been found it will be added to all those numbers. This implies that
**if there were no gaps before a number, there will be no gaps after that number has been processed**.

For the next input of `7`

we can assert that:

- (4) Since the input set is ordered, there will be no number less than
`7`

- (5) If there is no number less than
`7`

, then `6`

cannot be obtained

We can come to a conclusion that:

- (6)
**the first gap represents the minimum unobtainable number**.

## Algorithm

Because of (3) and (6), we don't actually need the `numbers`

array, we only need a single value, `max`

to **represent the maximum number found so far**.

This way, if the next number `n`

is greater than `max + 1`

, then a gap would have been made, and `max + 1`

is the minimum unobtainable number.

Otherwise, `max`

becomes `max + n`

. If we've run through the entire `S`

, the result is `max + 1`

.

Actual code (C#, easily converted to C):

```
static int Calculate(int[] S)
{
int max = 0;
for (int i = 0; i < S.Length; i++)
{
if (S[i] <= max + 1)
max = max + S[i];
else
return max + 1;
}
return max + 1;
}
```

Should run pretty fast, since it's obviously linear time (O(n)). Since the input to the function should be sorted, with quicksort this would become O(nlogn). I've managed to get results `M = N = 100000`

on 8 cores in just under 5 minutes.

With numbers upper limit of 10^9, a radix sort could be used to approximate O(n) time for the sorting, however this would still be way over 2 seconds because of the sheer amount of sorts required.

**But**, we can use **statistical probability of 1 being randomed** to eliminate subsets *before* sorting. On the start, check if 1 exists in `S`

, if not then every query's result is 1 because it cannot be obtained.

Statistically, if we random from 10^9 numbers 10^5 times, we have 99.9% chance of not getting a single 1.

Before each sort, check if that subset contains 1, if not then its result is one.

With this modification, the code runs in 2 miliseconds on my machine. Here's that code on http://pastebin.com/rF6VddTx