Let you have array `A {Ai, 1 <= i <= n }`

`F(i)`

- Maximum sum of subarray `Aj { 1 <= j <= i }`

, then

`F(0) = 0`

- empty subarray

`F(1) = A(1)`

- only first element

```
F(i) = max(F(i-2) + A(i), F(i-1)) , 2 <= i <= n
```

`F(n)`

- answer

C++ implementation:

```
int GetMaximumSubarraySum(const vector<int>& a)
{
// note that vector a have 1-based index
vector<int> v(a.size());
v[0] = 0;
v[1] = a[1];
for(int i =2; i < a.size(); i++)
v[i] = max(v[i-2] + a[i], v[i-1]);
return v.back();
}
```

**Explanation:**

First, main idea is to use dynamic programming.
We try to solve task for array with N element by using known answer for array with `N-1`

and `N-2`

first elements. If `N = 0`

the answer is `0`

and if `N = 1`

the answer is `A[1]`

. It's clear. For `N >= 2`

we have 2 different ways:

Use element `A[N],`

then the answer is `A[N] + F[N-2]`

(because we can't use A[N-1] element and `F[N-2]`

is the best solution for subarray `1..N-2`

, we don't care about if `F[N-2]`

element is used or not, this is just the best solution for subarray `1..N-2`

.

Don't use element `A[N]`

, then the answer is `F[N-1]`

(because we can use A[N-1] element and `F[N-1]`

is the best solution for subarray `1..N-1`

, also we don't care about if `F[N-1]`

element is used or not.

So we need to get max of this 2 situations.
To solve the task you need calculate `F[N]`

in increasing order and memorize answers.

Let see at your example:

`[12, 8, 9, 10]`

`F[0] = 0`

`F[1] = 12`

- use 1-st element

`F[2] = max(F[0]+A[2], F[1]) = max(8, 12) = 12`

- use 1-st element

`F[3] = max(F[1]+A[3], F[2]) = max(21, 12) = 21`

- use 1-st, 3-rd element

`F[4] = max(F[2]+A[4], F[3]) = max(22, 21) = 22`

- use 1-st, 4-th element

The answer is `F[4] = 22`

.

Pearls of Functional Algorithm Design. Try modifying the solution to solve your problem – n.m. Nov 4 '11 at 9:09