Let `n`

be the length of the initial board, and let `board[i]`

be the `i`

-th symbol (from the left, 1-based indices) in the initial board, and `board[i..j]`

the segment of the initial board between the indices `i`

and `j`

inclusive.

Let us call `i`

a winning length if the player whose turn it is when `board[1..i]`

is left can force a win, and a losing length if each possible move from `board[1..i]`

leaves a winning length for the other player.

0 is a losing length (no possible move at all), and 1 is a winning length (removing the only remaining symbol immediately wins).

Each length is either winning or losing: if any possible move leaves a losing length for the other player, we can force a win by choosing that move, otherwise it's a losing length by definition.

We can find out whether we can force a win, together with a winning strategy if that is the case by noting for each length if it is losing (mark as `-1`

) or what a win-forcing move would be (a non-negative integer `k`

such that removing `C[k]`

from the end of the remaining board leaves a losing length for the opponent; such a `k`

is generally not unique, any will do).

Pseudocode (C-ish):

```
int moves[n+1];
// initialise all lengths to losing
for(i = 0; i <= n; ++i) {
moves[i] = -1;
}
moves[1] = board[i]; // win by removing the last symbol
for(i = 2; i <= n; ++i) {
if (board[i] == 0) {
// no choice, the only code ending with a 0 is C[0]
moves[i] = moves[i-1] < 0 ? 0 : -1;
} else {
k = 1;
while(C[k] is_suffix_of board[1..i]) {
if (moves[i - fib(k)] < 0) {
// found a winning move
moves[i] = k;
break;
}
++k;
}
// we either found a winning move and noted it, or leave the position as losing
}
}
```

`moves[n]`

tells us whether the first player can force a win, and if so, how.

The advantage over a pure brute-force is that it saves a lot of recomputation, since all states but the first few are reachable in many ways.

The `C[k] is_suffix_of board[1..i]`

check is the most costly operation, it can be somewhat improved by noting that `C[k+1]`

is the concatenation of `C[k-1]`

and `C[k]`

in that order, so when you know that `C[k]`

is a suffix of `board[1..i]`

, you only need to check whether `C[k-1]`

is a suffix of `board[1..(i-fib(k))]`

.

`101`

and`01101`

, unless I misunderstood the rules. – Daniel Fischer Nov 4 '12 at 13:21