About your recurrence relation:

It appears somewhat difficult because the write-up suggests, that for E(1,N) we need E(2,..) and E(3,..), each of which in turn requires other entries with yet higher "i", etcetera.

Now, rearrange the terms such that we have the E-term with the highest "i" isolated (a good idea in general with recurrence relations is to have a look at different arrangements to isolate a particular index - the highest, the lowest, the middle one, ...):

E(i+2,j) = E(i,j) - E(i,j-2) - E(i+1,j-1) - A(i) - A(j)

Then, shift all i down by 2 (simply rewriting the formula)

E(i,j) = E(i-2,j) - E(i-2,j-2) - E(i-1,j-1) - A(i-2) - A(j).

Then, for {i=1, j=N}, which is what you're looking for, we get:

E(1,N) = E(-1,N) - E(-1,N-2) - E(0,N-1) - A(-1) - A(N) = -A(N), because all other terms are zero.

(I assume, of course, that E(i,j) and A(i) are zero for i=0 / j=0; your specification was presumably incomplete when you specified the zero-values only for NEGATIVE indices, but not for the zero-indices).

Then, about your (edited) description of the underlying case - two players taking in turn from A, arbitrarily from left or right, until A is exhausted:

From the previous result, I don't think it's likely that your recurrence relation describes the underlying game, given the outcome -A(N)... Therefore, leave that recurrence relation aside (it's solved anyway for i=1). and have a look at the game itself for what relations we may derive.

[CONTINUED AFTER EDIT]

So far, I haven't come up with something that I can cast in a closed form, i.e. something that is faster than processing some kind of recurrence relations. For the moment, therefore, let's write down how we might describe the game in a way that lends itself to calculation.

Define the following quantities:

Let X(i,k) be the probability that item #i (in array A) still exists (i.e. has not yet been taken by any player) at the end of turn #k (counting turns from both players). Of course, k runs in our game from 1 to N, and so does i. For verification purposes we may note, that X(i,N) must be zero for all i: at the end of the game all elements have been taken.

In case we may need (in formula-evaluations) any values of X(i,k) outside the "normal" range, we assess:

```
X(i,k)=1 for {1<=i<=N; k=0}: initially all elements in A are still there.
X(i,k)=0 whenever i<1 or i>N: no elements ever exist outside the (original) range of A.
```

Next, let T(i,k) be the probability that element #i is taken (by any player) at turn #k exactly.
That must be 0.5 * the probability that it is the leftmost element (currently), which is equivalent to saying that element #(i-1) does NOT exist at the end of the PREVIOUS turn, plus 0.5 * the probability that it is the rightmost element (currently), which in turn amounts to saying that element #(i+1) does not exist at the end of the previous turn, while all of that must be multiplied by the probability that element #i itself exists in the first place:

```
T(i,k) = X(i,k-1) * ( (1-X(i-1,k-1)) + (1-X(i+1,k-1)) ) / 2
```

The probability X(i,k) that element #i still exists after turn #k is the probability that it existed at the end of the previous turn, minus the probability that it is taken at turn #k:

```
X(i,k) = X(i,k-1) - T(i,k)
```

The probability that element #i winds up with player#1 is the summation over all turns k of T(i,k), but only counting HIS turns. Let's denote that quantity by P(i,1), where 1 stands for player #1.

```
P(i,1) = sum{ k=1,3,...: T(i,k) }
```

Likewise, for player #2:

```
P(i,2) = sum{ k=2,4,...: T(i,k) }
```

The expected score of player #1 is then the sum S(1):

```
S(1) = sum( i=1..N: P(i,1)*A(i) }, and likewise for player #2: S(2) = sum( i=1..N: P(i,2)*A(i) }
```

Looking at the above formula's I don't see a way to avoid an O(N2) method as regards time. Memory-usage can be O(N) as we may keep running totals and discard older 'element-wise'-data that won't be needed anymore. Given that - assuming you're not processing arrays A that are excessively long - the players wouldn't survive! - the O(n2) time-performance shouldn't be such an issue in practice.

```
int N = sizeof(A);
// note on the code below: we'll use i as an integer running over the elements in A, and k running over the turns that players make.
// while in human parlance we would have them (both) run from 1 to N, the zero-based arrays of C++ make it more convenient to let them
// run from 0 to N-1.
// initialize the running totals P(i), the accumulated (over turns) probabilities that element #i winds up with player #1.
// if we ever need the same for player #2, it's values are of course 1-P (that is: at the end of the game).
double* P = new double[N];
for (int i=0; i<N; i++)
{
P[i] = 0; // before we start, there's little chance that player #1 has already taken any element.
}
// initialize the existence-array for the elements.
int* X = new int[N];
for (int i=0; i<N; i++)
{
X[i] = 1; // initially all elements exist, i.e. have not yet been taken by any player.
}
// declare an array for processing the probabilities that elements are taken at a particular turn.
double* T = new double[N];
// iterate over the turns.
for (int k=0; k<N; k++)
{
// for each element, calculate the probability that it is taken NOW.
// the current values of X - the existence array - refer to the (end of the) previous turn.
for (int i=0; i<N; i++)
{
// note: take care of the boundaries i=0 and i=N-1.
if (i == 0)
{
T[i] = X[i] * ( 2 - X[i+1] ) / 2;
}
else if (i == N-1)
{
T[i] = X[i] * ( 2 - X[i-1] ) / 2;
}
else
{
T[i] = X[i] * ( 2 - X[i-1] - X[i+1] ) / 2;
}
} // element i
// with the take-probabilities for this turn in place, update P - only at odd turns (i.e. k=even): P is for player #1 only.
if (k % 2 == 0)
{
for (int i=0; i<N; i++)
{
P[i] += T[i];
}
}
// finally - in this turn - update the existence array.
for (int i=0; i<N; i++)
{
X[i] -= T[i];
}
} // turn k
// result: calculate the expected score for player #1.
double score = 0;
for (int i=0; i<N; i++)
{
score += P[i] * A[i];
}
```

--