module Model where import Data.Array import Data.Map (Map) import Data.Map qualified as Map import Graphics.Vty import Control.Monad import Data.Maybe import Data.Set qualified as Set import Data.Set (Set) type Coord = (Int, Int) data Box = Box { boxLocation :: Location, boxType :: BoxType, boxColor :: Attr } deriving (Show, Read, Eq) boxWalls :: World -> Box -> Array Coord Bool boxWalls world box = case boxType box of Original walls -> walls Link c -> boxWalls world (worldBoxes world Map.! c) data BoxType = Original (Array Coord Bool) | Link Char deriving (Show, Read, Eq) data Location = Location Char Int Int deriving (Read, Show, Ord, Eq) data World = World { worldBoxes :: Map Char Box, worldMe :: Char, worldButtons :: Set Location, worldHome :: Location } deriving (Show, Read, Eq) makeWalls :: [String] -> Array Coord Bool makeWalls rows = listArray ((ylo,xlo),(yhi,xhi)) (map (' '/=) (concat rows)) where h = length rows w = length (head rows) (xlo,xhi) = mkRange w (ylo,yhi) = mkRange h mkRange :: Int -> (Int,Int) mkRange n = (- (n-1)`div`2, n`div`2) boxSize :: World -> Box -> Int boxSize world box = yhi-ylo+1 where ((ylo,_),(yhi,_)) = bounds (boxWalls world box) solid :: Int -> Array Coord Bool solid n = makeWalls (replicate n (replicate n 'x')) -- Move an object -- 1. remove it from the world -- 2. compute where it would move to -- 3. a. that spot is empty -- b. try to move that object forward -- c. try to move that object backward into me move :: World -> (Int,Int) -> World move world dir = case moveBlock world Map.empty (myLocation world) dir 0 of Nothing -> world Just changes -> let f box = box { boxLocation = Map.findWithDefault (boxLocation box) (boxLocation box) changes } in world { worldBoxes = fmap f (worldBoxes world)} myLocation :: World -> Location myLocation world = boxLocation (worldBoxes world Map.! worldMe world) isWall :: World -> Location -> Bool isWall world (Location n y x) = case Map.lookup n (worldBoxes world) of Nothing -> True Just box -> boxWalls world box ! (y,x) type Movement = (Int, Int) moveBlock :: World -> Map Location (Int, Location) -> Location -> Movement -> Rational {- ^ offset -} -> Maybe (Map Location Location) -- moving into a wall, not possible moveBlock world _ loc _ _ | isWall world loc = Nothing -- move introduced a loop, trim off the tail and report success moveBlock _ visited loc _ _ | Just (n,_) <- Map.lookup loc visited = Just (fmap snd (Map.filter (\(a,_)->a >= n) visited)) moveBlock world visited loc dir offset = case [(n,box) | (n,box) <- Map.assocs (worldBoxes world), boxLocation box == loc] of -- moving an empty space, so we're done [] -> Just (fmap snd visited) -- moving a box (name,box):_ -> do (loc', offset') <- nextLoc world dir loc offset --traceM (show "Next loc " ++ show loc' ++ " offset " ++ show offset') guard (not (isWall world loc')) moveBlock' world visited loc loc' dir name box offset' moveBlock' :: World -> Map Location (Int, Location) -> Location -> Location -> Movement -> Char -> Box -> Rational {- ^ offset -} -> Maybe (Map Location Location) moveBlock' world visited loc loc' dir name box offset = msum [moveTo, moveInto, moveToEat] where moveTo = do moveBlock world (addVisited loc loc' visited) loc' dir 0 moveInto = do (n,b) <- boxAt world loc' let (locI, offset') = enterLoc world n b dir offset moveBlock' world visited loc locI dir name box offset' -- beware epsilon! moveToEat = do let dir' = invert dir let (locE, _) = enterLoc world name box dir' 0 (name', box') <- boxAt world loc' moveBlock' world (addVisited loc loc' visited) loc' locE dir' name' box' 0 enterLoc :: World -> Char -> Box -> Movement -> Rational -> (Location, Rational) enterLoc world name box dir@(dy,dx) offset = case dir of (-1, 0) -> go yhi (midpoint xlo xhi offset) ( 1, 0) -> go ylo (midpoint xlo xhi offset) ( 0,-1) -> go (midpoint ylo yhi offset) xhi ( 0, 1) -> go (midpoint ylo yhi offset) xlo _ -> error "enterLoc: bad direction" where name' = case boxType box of Link c -> c Original{} -> name ((ylo,xlo),(yhi,xhi)) = bounds (boxWalls world box) go y x = (Location name' y x, fromIntegral(boxSize world box) * offset - fromIntegral ((abs dy *x + abs dx*y))) boxAt :: World -> Location -> Maybe (Char, Box) boxAt world loc = listToMaybe [(n,b) | (n,b) <- Map.assocs (worldBoxes world), boxLocation b == loc] invert :: Movement -> Movement invert (dy,dx) = (-dy, -dx) midpoint :: Int -> Int -> Rational -> Int midpoint lo hi offset = round (offset * fromIntegral (hi-lo+1)) addVisited :: Location {- ^ start -} -> Location {- ^ end -} -> Map Location (Int, Location) -> Map Location (Int, Location) addVisited k v m = Map.insert k (Map.size m, v) m nextLoc :: World -> Movement -> Location -> Rational -> Maybe (Location, Rational) nextLoc world (dy, dx) = go Set.empty where go _ (Location b y x) offset | Just box <- Map.lookup b (worldBoxes world) , inRange (bounds (boxWalls world box)) (y+dy, x+dx) = Just (Location b (y+dy) (x+dx), offset) go visited (Location b y x) offset | Just box <- Map.lookup b (worldBoxes world) , Set.notMember b visited = go (Set.insert b visited) (boxLocation box) $ (offset + fromIntegral (abs dy*x+abs dx*y)) / fromIntegral (boxSize world box) go _ _ _ = Nothing