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
Now it's easy to see that the sum of values for indices
SUM(q) - SUM(p-1) (with the special case that
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
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.
p <- 1
q <- 1
while SUM(q) - SUM(p-1) < K
q <- q + 1
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.
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
while q < N and subsum < K
q <- q + 1
subsum <- subsum + VAL(q)
-- Check the length against our current best
len <- q - p + 1
if len < bestlen
subsum <- subsum - VAL(p)
p <- p + 1
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
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
q at every step. We only have to add or subtract one value whenever we advance one of the search pointers.
Hope that helps.