Define `F(i, j)`

as the maximal pairwise sum that can be achieved by stable merging `Ai...An`

and `Bj...Bn`

.

At each step in the merge, we can choose one of three options:

- Take the first two remaining elements of
`A`

.
- Take the first remaining element of
`A`

and the first remaining element of `B`

.
- Take the first two remaining elements of
`B`

.

Thus, `F(i, j)`

can be defined recursively as:

```
F(n, n) = 0
F(i, j) = max
(
AiAi+1 + F(i+2, j), //Option 1
AiBj + F(i+1, j+1), //Option 2
BjBj+1 + F(i, j+2) //Option 3
)
```

To find the optimal merging of the two lists, we need to find `F(0, 0)`

, naively, this would involve computing intermediate values many times, but by caching each `F(i, j)`

as it is found, the complexity is reduced to `O(n^2)`

.

Here is some quick and dirty c++ that does this:

```
#include <iostream>
#define INVALID -1
int max(int p, int q, int r)
{
return p >= q && p >= r ? p : q >= r ? q : r;
}
int F(int i, int j, int * a, int * b, int len, int * cache)
{
if (cache[i * (len + 1) + j] != INVALID)
return cache[i * (len + 1) + j];
int p = 0, q = 0, r = 0;
if (i < len && j < len)
p = a[i] * b[j] + F(i + 1, j + 1, a, b, len, cache);
if (i + 1 < len)
q = a[i] * a[i + 1] + F(i + 2, j, a, b, len, cache);
if (j + 1 < len)
r = b[j] * b[j + 1] + F(i, j + 2, a, b, len, cache);
return cache[i * (len + 1) + j] = max(p, q, r);
}
int main(int argc, char ** argv)
{
int a[] = {2, 1, 3};
int b[] = {3, 7, 9};
int len = 3;
int cache[(len + 1) * (len + 1)];
for (int i = 0; i < (len + 1) * (len + 1); i++)
cache[i] = INVALID;
cache[(len + 1) * (len + 1) - 1] = 0;
std::cout << F(0, 0, a, b, len, cache) << std::endl;
}
```

If you need the actual merged sequence rather than just the sum, you will also have to cache which of `p, q, r`

was selected and backtrack.