This seems to be a problem for dynamic programming. When you build your array, you build another array containing the cumulative sum up to each particular index. So each `i`

in that array has the sums from `1..i`

.

Now it's easy to see that the sum of values for indices `p..q`

is `SUM(q) - SUM(p-1)`

(with the special case that `SUM(0)`

is `0`

). Obviously I'm using 1-based indices here... This operation is O(1), so now you just need an O(n) algorithm to find the best one.

A simple solution is to keep track of a `p`

and `q`

and walk these through the array. You expand with `q`

to begin. Then you contract `p`

and expand `q`

repeatedly, like a caterpillar crawling through your array.

To expand `q`

:

```
p <- 1
q <- 1
while SUM(q) - SUM(p-1) < K
q <- q + 1
end while
```

Now `q`

is at the position where the subarray sum has just exceeded (or is equal to) `K`

. The length of the subarray is `q - p + 1`

.

After the `q`

loop you test whether the subarray length is less than your current best. Then you advance `p`

by one step (so that you don't accidentally skip over the optimal solution) and go again.

You don't really need to create the `SUM`

array... You can just build the subarray sum as you go... You would need to go back to using the 'real' `p`

instead of the one just before.

```
subsum <- VAL(1)
p <- 1
q <- 1
while q <= N
-- Expand
while q < N and subsum < K
q <- q + 1
subsum <- subsum + VAL(q)
end while
-- Check the length against our current best
len <- q - p + 1
if len < bestlen
...
end if
-- Contract
subsum <- subsum - VAL(p)
p <- p + 1
end while
```

Notes:

**j_random_hacker said:** it would help to explain exactly why it is acceptable to examine just the O(n) distinct subarrays that this
algorithm examines, instead of all O(n^2) possible distinct subarrays

The dynamic programming philosophy is:

- do not follow solution paths that will lead to a non-optimal result; and
- use the knowledge of previous solutions to compute a new solution.

In this case a single solution candidate (some `(p,q)`

such that `p <= q`

) is computed by summing of the elements. Because those elements are positive integers, we know that for any solution candidate `(p,q)`

, the solution candidate `(p,q+1)`

will be larger.

And so we know that if `(p,q)`

is a minimal solution then `(p,q+1)`

is not. We end our search as soon as we have a candidate, and test whether that candidate is better than any we have seen so far. That means for each `p`

, we only need to test one candidate. This leads to both `p`

and `q`

only ever increasing, and thus the search is linear.

The other part of this (using previous solutions) comes from recognising that `sum(p,q+1) = sum(p,q) + X(q+1)`

and similarly `sum(p+1,q) = sum(p,q) - X(p)`

. Therefore, we do not have to sum all elements between `p`

and `q`

at every step. We only have to add or subtract one value whenever we advance one of the search pointers.

Hope that helps.