You can answer this question from CLRS, which includes a tip:

Use the following ideas to develop a nonrecursive, linear-time algorithm for the
maximum-subarray problem.

Start at the left end of the array, and progress toward
the right, keeping track of the maximum subarray seen so far.

Knowing a maximum sub array of `A[1..j]`

, extend the answer to find a maximum subarray ending at index `j+1`

by using the following observation:

a maximum sub array of `A[1..j+1]`

is either a maximum sub array of `A[1..j]`

or a sub array `A[i..j+1]`

, for some `1 <= i <= j + 1`

.

Determine a maximum sub array of the form `A[i..j+1]`

in constant time based on knowing a maximum subarray ending at index `j`

.

```
max-sum = A[1]
current-sum = A[1]
left = right = 1
current-left = current-right = 1
for j = 2 to n
if A[j] > current-sum + A[j]
current-sum = A[j]
current-left = current-right = j
else
current-sum += A[j]
current-right = j
if current-sum > max-sum
max-sum = current-sum
left = current-left
right = current-right
return (max-sum, left, right)
```

`Kadane's algorithm`

– noMAD Aug 28 '12 at 19:08`maxsum()`

that implements Kadane's algorithm and its modification`maxsumseq()`

that computes indexes and returns the subsequence from Greatest subsequential sum problem. – J.F. Sebastian Sep 30 '12 at 13:19