I created an algorithm based on flood fill to collect all of the tiles that are touching the ones we just dropped, one of those must then intersect the centre tile for the play to be valid.

The algorithm starts at each tile you dropped, then checks each of the surrounding squares for a tile, if the tile exists in a particular direction will then add it to a Set and recursively do the same for each tile touching this new tile, if no tile exists it will exit the function. The recursion ends when we run out of tiles in all directions from the letters we played.

```
func getFilledSquare(c: Coordinate) -> Square? {
return squares
|> { s in filter(s) { $0.c == c && $0.tile != nil } }
|> { s in first(s) }
}
func getAdjacentFilledSquares(c: Coordinate?, vertically v: Bool, horizontally h: Bool, original: Square, inout output: Set<Square>) {
// We may hit the original square several times in different directions, so we allow it through multiple times
if let coord = c, sq = getFilledSquare(coord) where sq == original || !output.contains(sq) {
output.insert(sq)
if h {
getAdjacentFilledSquares(coord.next(.Horizontal, d: 1, b: self), vertically: v, horizontally: h, original: original, output: &output)
getAdjacentFilledSquares(coord.next(.Horizontal, d: -1, b: self), vertically: v, horizontally: h, original: original, output: &output)
}
if v {
getAdjacentFilledSquares(coord.next(.Vertical, d: 1, b: self), vertically: v, horizontally: h, original: original, output: &output)
getAdjacentFilledSquares(coord.next(.Vertical, d: -1, b: self), vertically: v, horizontally: h, original: original, output: &output)
}
}
}
```

It's open source and the method is called getAdjacentFilledSquares (a bit verbose I know). My repo is here: https://github.com/ChrisAU/Locution?files=1