Given `n`

integers, is there an `O(n)`

or `O(n log n)`

algorithm that can compute the maximum value of a mathematical expression that can be obtained by inserting the operators `-`

, `+`

, `*`

and parentheses between the given numbers? Assume only binary variants of the operators, so no unary minus, except before the first element if needed.

For example, given `-3 -4 5`

, we can build the expression `(-3) * (-4) * 5`

, whose value is `60`

, and maximum possible.

**Background:**

I stumbled upon this problem some time ago when studying genetic algorithms, and learned that it can be solved pretty simply with a classical genetic algorithm. This runs slowly however, and it's only simple in theory, as the code gets rather ugly in practice (evaluate the expression, check for correct placement of brackets etc.). What's more, we're not guaranteed to find the absolute maximum either.

All these shortcomings of genetic algorithms got me wondering: since we can don't have to worry about division, is there a way to do this efficiently with a more classic approach, such as dynamic programming or a greedy strategy?

**Update:**

Here's an F# program that implements the DP solution proposed by @Keith Randall together with my improvement, which I wrote in a comment to his post. This is very inefficient, but I maintain that it's polynomial and has cubic complexity. It runs in a few seconds for ~50 element arrays. It would probably be faster if written in a fully imperative manner, as a lot of time is probably wasted on building and traversing lists.

```
open System
open System.IO
open System.Collections.Generic
let Solve (arr : int array) =
let memo = new Dictionary<int * int * int, int>()
let rec Inner st dr last =
if st = dr then
arr.[st]
else
if memo.ContainsKey(st, dr, last) then
memo.Item(st, dr, last)
else
match last with
| 0 -> memo.Add((st, dr, last),
[
for i in [st .. dr - 1] do
for j in 0 .. 2 do
for k in 0 .. 2 do
yield (Inner st i j) * (Inner (i + 1) dr k)
] |> List.max)
memo.Item(st, dr, last)
| 1 -> memo.Add((st, dr, last),
[
for i in [st .. dr - 1] do
for j in 0 .. 2 do
for k in 0 .. 2 do
yield (Inner st i j) + (Inner (i + 1) dr k)
] |> List.max)
memo.Item(st, dr, last)
| 2 -> memo.Add((st, dr, last),
[
for i in [st .. dr - 1] do
for j in 0 .. 2 do
for k in 0 .. 2 do
yield (Inner st i j) - (Inner (i + 1) dr k)
] |> List.max)
memo.Item(st, dr, last)
let noFirst = [ for i in 0 .. 2 do yield Inner 0 (arr.Length - 1) i ] |> List.max
arr.[0] <- -1 * arr.[0]
memo.Clear()
let yesFirst = [ for i in 0 .. 2 do yield Inner 0 (arr.Length - 1) i ] |> List.max
[noFirst; yesFirst] |> List.max
let _ =
printfn "%d" <| Solve [|-10; 10; -10|]
printfn "%d" <| Solve [|2; -2; -1|]
printfn "%d" <| Solve [|-5; -3; -2; 0; 1; -1; -1; 6|]
printfn "%d" <| Solve [|-5; -3; -2; 0; 1; -1; -1; 6; -5; -3; -2; 0; 1; -1; -1; 6; -5; -3; -2; 0; 1; -1; -1; 6; -5; -3; -2; 0; 1; -1; -1; 6; -5; -3; -2; 0; 1; -1; -1; 6; -5; -3; -2; 0; 1; -1; -1; 6;|]
```

Results:

1000

6

540

2147376354

The last one is most likely an error due to overflow, I'm just trying to show that a relatively big test runs too fast for this to be exponential.