The idea is to split your sequence in half, find the answers for both halves, then use that to find the answer for the entire sequence.

Assume you have a sequence `[left, right]`

. Let `m = (left + right) / 2`

. Now, the maximum sum subsequence (`MSS`

) of `[left, right]`

is either `MSS(left, m)`

, `MSS(m + 1, right)`

or a sequence that starts in `[left, m]`

and ends somewhere in `[m + 1, right]`

.

Pseudocode:

```
MSS(left, right)
if left = right then return sequence[left]
m = (left + right) / 2
leftMSS = MSS(left, m)
rightMSS = MSS(m + 1, right)
maxLeft = -inf // find the maximum sum subsequence that ends with m and starts with at least left
cur = 0
i = m
while i >= left do
cur += sequence[i]
if cur > maxLeft
maxLeft = cur
maxRight = -inf // find the maximum sum subsequence that starts with m + 1 and ends with at most right
cur = 0
i = m + 1
while i <= right
cur += sequence[i]
if cur > maxRight
maxRight = cur
return max(leftMSS, rightMSS, maxLeft + maxRight)
```

This is `O(n log n)`

because the recursion three has height `O(log n)`

and at each level of the tree we do `O(n)`

work.

Here is how it would run on `-2, 4, -1, 3, 5, -6, 1, 2`

:

```
0 1 2 3 4 5 6 7
-2 4 -1 3 5 -6 1 2
MSS(0, 7) = 11
/ \
MSS(0, 3) = 6 MSS(4, 7) = 5 ------
/ \ | \
MSS(0, 1) = 4 MSS(2, 3) = 3 MSS(4, 5) = 5 NSS(6, 7) = 3
/ \ / \
MSS(0, 0) = -2 MSS(1, 1) = 4 MSS(2, 2) = -1 MSS(3, 3) = 3
```

Of interest is the computation of `MSS(0, 3)`

and `MSS(0, 7)`

, since these do not simply take the max of their children. For `MSS(0, 3)`

we try to make as large a sum as possible adding consecutive elements starting with the middle of the interval (1) and going left. This max is `4`

. Next we do the same starting with the middle of the interval + 1 and going right. This max is `2`

. Adding these together gets us a maximum sum subsequence with the sum of `6`

, which is larger than the maximum sum subsequence of the two child intervals, so we take this one instead.

The reasoning is similar for `MSS(0, 7)`

.

contiguous subsequencesum? The maximum subset sum is trivial: toss out all the negative elements. – Ted Hopp Jul 26 '11 at 22:47