Chris's answer fails on the list [9,10,9], producing 10 instead of 9+9 = 18.

Joe is not quite right. Traveling salesman requires you to visit every city, whereas there's no analog to that here.

One possible solution would be the recursive solution:

```
function Max_route(A)
if A's length = 1
A[0]
else
maximum of
A[0]+Max_route(A[2...])
Max_route[1...]
```

This has the same big-O as a naive fibonacci function, and should yield to some of the same optimizations (e.g. memoization) if you care about efficiency in addition to simply getting a correct answer.

-- MarkusQ

[Edit] ---

Because some people don't seem to be getting this, I want to explain what I meant by memoization and why it matters.

You could wrap the function above so that it only computed the value for each array once (the first time it was called), and on subsequent calls would simply return the saved result. This would take O(n) space but would return in constant time. That means the whole algorithm would return in O(n) time, better than the exponential time of the less cluttered version above. I was assuming this was well understood.

[Second edit]------------------------------

If we expand the above a bit and tease it apart we get:

```
f [] :- [],0
f [x] :- [x],x
f [a,b] :- if a > b then [a],a else [b],b
f [a,b,t] :-
ft = f t
fbt = f [b|t]
if a + ft.sum > fbt.sum
[a|ft.path],a+ft.sum
else
fbt
```

Which we can unroll into a pseudo basic using only size n arrays of integers and booleans, and the operations of 1) array indexing and indexed array assignment, 2) integer math, including comparison, 3) if/then/else, and 4) one single loop of O(n):

```
dim max_sum_for_initial[n],next_to_get_max_of_initial[n],use_last_of_initial[n]
max_sum_for_initial[0] = 0
next_to_get_max_of_initial[0] = -1
use_last_of_initial[0] = false
max_sum_for_initial[1] = a[0]
next_to_get_max_of_initial[1] = -1
use_last_of_initial[1] = true
if a[0] > a[1]
max_sum_for_initial[2] = a[0]
next_to_get_max_of_initial[2] = 0
use_last_of_initial[2] = false
else
max_sum_for_initial[2] = a[1]
next_to_get_max_of_initial[1] = -1
use_last_of_initial[2] = true
for i from 3 to n
if a[i]+max_sum_for_initial[i-2] > max_sum_for_initial[i-1]
max_sum_for_initial[i] = a[i]+max_sum_for_initial[i-2]
next_to_get_max_of_initial[i] = i-2
use_last_of_initial[i] = true
else
max_sum_for_initial[i] = max+sum_for_initial[i-1]
next_to_get_max_of_initial[i] = i-1
use_last_of_initial[i] = false
```

At the end we can extract the results (in reverse order):

```
for i = n; i >= 0; i = next_to_get_max_of_initial[i]
if use_last_of_initial[i] then print a[i]
```

Note that what we just did manually is something that a good compiler for a modern language should be able to accomplish with tail recursion, memoization, etc.

I hope that is clear enough.

-- MarkusQ

It's O(n).

sigh– JB King Feb 25 '09 at 1:28