I have asked this question in code review but didn't get any answers. I've also asked a similar question here but I've come back with a revised implementation.
I wrote a BFS implementation that walks a tile-based field. It takes a function that should return true for walkable tiles and false for walls. It also takes the start and end points. It currently takes about 5 seconds to find the shortest path from (0, 0) to (1000, 1000) which isn't bad, but it really isn't great.
Here's my code:
import qualified Data.HashSet as H import Data.Maybe (mapMaybe, isNothing) import Data.List (foldl') bfs :: (Int -> Int -> Bool) -> -- The field function. Returns True if tile is empty, False if it's a wall (Int, Int) -> -- Starting position (Int, Int) -> -- Final position Int -- Minimal steps bfs field start end = minSteps H.empty [start] 0 where minSteps visited queue steps |end `elem` queue = steps + 1 |otherwise = minSteps newVisited newQueue (steps + 1) where (newVisited, newQueue) = foldl' aggr (visited, ) queue aggr (vis, q) node = if H.member node vis then (H.insert node vis, neighbors node ++ q) else (vis, q) neighbors (nx, ny) = filter (uncurry field) $ map (\(x, y) -> (nx + x, ny + y)) [(1, 0), (0, -1), (-1, 0), (0, 1)] hugeField x y = x >= 0 && x <= 1000 && y >= 0 && y <= 1000 main = print $ bfs hugeField (0, 0) (1000, 1000)
Is there anything here that I could improve? Maybe take a different approach?