hfiar-0.1.2: src/HFiaR.hs
-- | This module defines the HFiaR monad and all the actions you can perform in it
module HFiaR (
-- * Monad controls
HFiaRT, play, eval,
-- * Types
Game, Player, Tile(..), HFiaRError(..), HFiaRResult(..),
-- * Actions
dropIn, player, board, result
) where
import Control.Monad.State
-- | Posible errors in the HFiaR Monad
data HFiaRError = GameEnded | GameNotEnded | InvalidColumn | FullColumn
deriving (Eq)
instance Show HFiaRError where
show GameEnded = "Game ended"
show GameNotEnded = "Game is on course yet"
show InvalidColumn = "That column doesn't exist"
show FullColumn = "That column is full"
-- | Posible tiles (just green or red ones)
data Tile = Red | Green
deriving (Eq, Show)
-- | Posible players (each one with his tile colour)
data Player = Pl {tiles :: Tile}
deriving (Eq)
instance Show Player where
show (Pl t) = show t
-- | Posible results for the game
data HFiaRResult = Tie | WonBy Player
deriving (Eq, Show)
-- | Game description
data Game = OnCourse {gamePlayer :: Player,
gameBoard :: [[Tile]]} |
Ended {gameResult :: HFiaRResult,
gameBoard :: [[Tile]]}
deriving (Eq, Show)
-- | Generic HFiaRT type
newtype HFiaRT m a = HFT {state :: StateT Game m a}
deriving (Monad, MonadIO, MonadTrans)
instance Monad m => MonadState Game (HFiaRT m) where
get = HFT $ get
put = HFT . put
play :: Monad m => HFiaRT m a -> m Game
play actions = (state actions) `execStateT` (OnCourse (Pl Green) (replicate 7 []))
eval :: Monad m => HFiaRT m a -> m a
eval actions = (state actions) `evalStateT` (OnCourse (Pl Green) (replicate 7 []))
--------------------------------------------------------------------------------
-- | Drop a tile in a column
dropIn :: Monad m => Int -- ^ Column number
-> HFiaRT m (Either HFiaRError ())
dropIn c | c < 0 = return $ Left InvalidColumn
| 6 < c = return $ Left InvalidColumn
| otherwise =
do
game <- get
case game of
Ended{} -> return $ Left GameEnded
OnCourse{gameBoard = board,
gamePlayer= player} ->
if length (board !! c) == 7
then return $ Left FullColumn
else
let newBoard = insertAt c (tiles player) board
newResult= if (isWinner c player newBoard) then WonBy player else Tie
newGame = if (full newBoard || (newResult == WonBy player))
then Ended{gameResult = newResult,
gameBoard = newBoard}
else OnCourse{gameBoard = newBoard,
gamePlayer= otherPlayer player}
in put newGame >>= return . Right
where insertAt :: Int -> a -> [[a]] -> [[a]]
insertAt i x xss = (take i xss) ++ ( (x : (xss !! i)) : drop (i+1) xss)
otherPlayer :: Player -> Player
otherPlayer Pl{tiles=Green} = Pl Red
otherPlayer Pl{tiles=Red} = Pl Green
full :: [[a]] -> Bool
full = all (\x -> 7 == length x)
isWinner :: Int -> Player -> [[Tile]] -> Bool
isWinner c Pl{tiles=p} b =
let col = b !! c
in ([p,p,p,p] == take 4 col) ||
fourIn (getRow (length col - 1) b) ||
fourIn (getDiagUpRight c (length col - 1) b) ||
fourIn (getDiagUpLeft c (length col - 1) b)
getRow :: Int -> [[Tile]] -> [Maybe Tile]
getRow r = map (cell r)
getDiagUpRight :: Int -> Int -> [[Tile]] -> [Maybe Tile]
getDiagUpRight c r xss = map (\i -> cell (i+r-c) (xss !! i)) [0..6]
getDiagUpLeft :: Int -> Int -> [[Tile]] -> [Maybe Tile]
getDiagUpLeft c r xss = map (\i -> cell (r+c-i) (xss !! i)) [0..6]
cell :: Int -> [Tile] -> Maybe Tile
cell c xs = if (c >= 0 && c < length xs)
then Just $ (reverse xs) !! c
else Nothing
fourIn :: [Maybe Tile] -> Bool
fourIn [] = False
fourIn (Nothing:xs) = fourIn xs
fourIn (Just p :xs) = ([Just p, Just p, Just p] == take 3 xs) || fourIn xs
-- | Player who's supposed to play the next tile
player :: Monad m => HFiaRT m (Either HFiaRError Player)
player = get >>= \game -> return $ case game of
Ended{} -> Left GameEnded
OnCourse{gamePlayer = p} -> Right p
-- | Current board distribution
board :: Monad m => HFiaRT m [[Tile]]
board = get >>= return . gameBoard
-- | If the game ended, returns the result of it
result :: Monad m => HFiaRT m (Either HFiaRError HFiaRResult)
result = get >>= \game -> return $ case game of
OnCourse{} -> Left GameNotEnded
Ended{gameResult = r} -> Right r