Day 17: Clumsy Crucible

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FAQ

    • Leo Uino@lemmy.sdf.org
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      11 months ago

      Yeah, finding a good way to represent the “last three moves” constraint was a really interesting twist. You beat me to it, anyway!

  • hades@lemm.ee
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    3 months ago

    Python

    749 line-seconds

    import collections
    import dataclasses
    import heapq
    
    import numpy as np
    
    from .solver import Solver
    
    
    @dataclasses.dataclass(order=True)
    class QueueEntry:
      price: int
      x: int
      y: int
      momentum_x: int
      momentum_y: int
      deleted: bool
    
    
    class Day17(Solver):
      lines: list[str]
      sx: int
      sy: int
      lower_bounds: np.ndarray
    
      def __init__(self):
        super().__init__(17)
    
      def presolve(self, input: str):
        self.lines = input.splitlines()
        self.sx = len(self.lines[0])
        self.sy = len(self.lines)
        start = (self.sx - 1, self.sy - 1)
        self.lower_bounds = np.zeros((self.sx, self.sy)) + np.inf
        self.lower_bounds[start] = 0
        queue: list[QueueEntry] = [QueueEntry(0, self.sx - 1, self.sy - 1, 0, 0, False)]
        queue_entries: dict[tuple[int, int], QueueEntry] = {start: queue[0]}
        while queue:
          cur_price, x, y, _, _, deleted = dataclasses.astuple(heapq.heappop(queue))
          if deleted:
            continue
          del queue_entries[(x, y)]
          self.lower_bounds[x, y] = cur_price
          price = cur_price + int(self.lines[y][x])
          for dx, dy in ((-1, 0), (1, 0), (0, -1), (0, 1)):
            nx, ny = x + dx, y + dy
            if not (0 <= nx < self.sx) or not (0 <= ny < self.sy):
              continue
            if price < self.lower_bounds[nx, ny]:
              self.lower_bounds[nx, ny] = price
              if (nx, ny) in queue_entries:
                queue_entries[(nx, ny)].deleted = True
              queue_entries[(nx, ny)] = QueueEntry(price, nx, ny, 0, 0, False)
              heapq.heappush(queue, queue_entries[(nx, ny)])
    
      def _solve(self, maximum_run: int, minimum_run_to_turn: int):
        came_from: dict[tuple[int, int, int, int], tuple[int, int, int, int]] = {}
        start = (0, 0, 0, 0)
        queue: list[QueueEntry] = [QueueEntry(self.lower_bounds[0, 0], *start, False)]
        queue_entries: dict[tuple[int, int, int, int], QueueEntry] = {start: queue[0]}
        route: list[tuple[int, int]] = []
        prices: dict[tuple[int, int, int, int], float] = collections.defaultdict(lambda: np.inf)
        prices[start] = 0
        while queue:
          _, current_x, current_y, momentum_x, momentum_y, deleted = dataclasses.astuple(heapq.heappop(queue))
          cur_price = prices[(current_x, current_y, momentum_x, momentum_y)]
          if deleted:
            continue
          if ((current_x, current_y) == (self.sx - 1, self.sy - 1) and
              (momentum_x >= minimum_run_to_turn or momentum_y >= minimum_run_to_turn)):
            previous = came_from.get((current_x, current_y, momentum_x, momentum_y))
            route.append((current_x, current_y))
            while previous:
              x, y, *_ = previous
              if x != 0 or y != 0:
                route.append((x, y))
              previous = came_from.get(previous)
            break
          for dx, dy in ((-1, 0), (1, 0), (0, -1), (0, 1)):
            dot_product = dx * momentum_x + dy * momentum_y
            if dot_product < 0 or dot_product >= maximum_run:
              continue
            if ((momentum_x or momentum_y) and dot_product == 0 and
                abs(momentum_x) < minimum_run_to_turn and abs(momentum_y) < minimum_run_to_turn):
              continue
            new_x, new_y = current_x + dx, current_y + dy
            if not (0 <= new_x < self.sx) or not (0 <= new_y < self.sy):
              continue
            new_momentum_x, new_momentum_y = (dx, dy) if dot_product == 0 else (momentum_x + dx, momentum_y + dy)
            new_position = (new_x, new_y, new_momentum_x, new_momentum_y)
            potential_new_price = cur_price + int(self.lines[new_y][new_x])
            if potential_new_price < prices[new_position]:
              queue_entry = queue_entries.get(new_position)
              if queue_entry:
                queue_entry.deleted = True
              queue_entries[new_position] = QueueEntry(potential_new_price + self.lower_bounds[new_x, new_y],
                                                       *new_position, False)
              came_from[new_position] = (current_x, current_y, momentum_x, momentum_y)
              prices[new_position] = potential_new_price
              heapq.heappush(queue, queue_entries[new_position])
        return sum(int(self.lines[y][x]) for x, y in route)
    
      def solve_first_star(self) -> int:
        return self._solve(3, 0)
    
      def solve_second_star(self) -> int:
        return self._solve(10, 4)
    
  • cvttsd2si@programming.dev
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    11 months ago

    Scala3

    Learning about scala-graph yesterday seems to have paid off already. This explicitly constructs the entire graph of allowed moves, and then uses a naive dijkstra run. This works, and I don’t have to write a lot of code, but it is fairly inefficient.

    import day10._
    import day10.Dir._
    import day11.Grid
    
    // standing on cell p, having entered from d
    case class Node(p: Pos, d: Dir)
    
    def connect(p: Pos, d: Dir, g: Grid[Int], dists: Range) = 
        val from = Seq(-1, 1).map(i => Dir.from(d.n + i)).map(Node(p, _))
        val ends = List.iterate(p, dists.last + 1)(walk(_, d)).filter(g.inBounds)
        val costs = ends.drop(1).scanLeft(0)(_ + g(_))
        from.flatMap(f => ends.zip(costs).drop(dists.start).map((dest, c) => WDiEdge(f, Node(dest, d), c)))
    
    def parseGrid(a: List[List[Char]], dists: Range) =
        val g = Grid(a.map(_.map(_.getNumericValue)))
        Graph() ++ g.indices.flatMap(p => Dir.all.flatMap(d => connect(p, d, g, dists)))
    
    def compute(a: List[String], dists: Range): Long =
        val g = parseGrid(a.map(_.toList), dists)
        val source = Node(Pos(-1, -1), Right)
        val sink = Node(Pos(-2, -2), Right)
        val start = Seq(Down, Right).map(d => Node(Pos(0, 0), d)).map(WDiEdge(source, _, 0))
        val end = Seq(Down, Right).map(d => Node(Pos(a(0).size - 1, a.size - 1), d)).map(WDiEdge(_, sink, 0))
        val g2 = g ++ start ++ end
        g2.get(source).shortestPathTo(g2.get(sink)).map(_.weight).getOrElse(-1.0).toLong
    
    def task1(a: List[String]): Long = compute(a, 1 to 3)
    def task2(a: List[String]): Long = compute(a, 4 to 10)
    
  • LeixB@lemmy.world
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    11 months ago

    Haskell

    import Data.Array.Unboxed
    import qualified Data.ByteString.Char8 as BS
    import Data.Char (digitToInt)
    import Data.Heap hiding (filter)
    import qualified Data.Heap as H
    import Relude
    
    type Pos = (Int, Int)
    
    type Grid = UArray Pos Int
    
    data Dir = U | D | L | R deriving (Eq, Ord, Show, Enum, Bounded, Ix)
    
    parse :: ByteString -> Maybe Grid
    parse input = do
      let l = fmap (fmap digitToInt . BS.unpack) . BS.lines $ input
          h = length l
      w <- fmap length . viaNonEmpty head $ l
      pure . listArray ((0, 0), (w - 1, h - 1)) . concat $ l
    
    move :: Dir -> Pos -> Pos
    move U = first pred
    move D = first succ
    move L = second pred
    move R = second succ
    
    nextDir :: Dir -> [Dir]
    nextDir U = [L, R]
    nextDir D = [L, R]
    nextDir L = [U, D]
    nextDir R = [U, D]
    
    -- position, previous direction, accumulated loss
    type S = (Int, Pos, Dir)
    
    doMove :: Grid -> Dir -> S -> Maybe S
    doMove g d (c, p, _) = do
      let p' = move d p
      guard $ inRange (bounds g) p'
      pure (c + g ! p', p', d)
    
    doMoveN :: Grid -> Dir -> Int -> S -> Maybe S
    doMoveN g d n = foldl' (>=>) pure . replicate n $ doMove g d
    
    doMoves :: Grid -> [Int] -> S -> Dir -> [S]
    doMoves g r s d = mapMaybe (flip (doMoveN g d) s) r
    
    allMoves :: Grid -> [Int] -> S -> [S]
    allMoves g r s@(_, _, prev) = nextDir prev >>= doMoves g r s
    
    solve' :: Grid -> [Int] -> UArray (Pos, Dir) Int -> Pos -> MinHeap S -> Maybe Int
    solve' g r distances target h = do
      ((acc, pos, dir), h') <- H.view h
    
      if pos == target
        then pure acc
        else do
          let moves = allMoves g r (acc, pos, dir)
              moves' = filter (\(acc, p, d) -> acc < distances ! (p, d)) moves
              distances' = distances // fmap (\(acc, p, d) -> ((p, d), acc)) moves'
              h'' = foldl' (flip H.insert) h' moves'
          solve' g r distances' target h''
    
    solve :: Grid -> [Int] -> Maybe Int
    solve g r = solve' g r (emptyGrid ((lo, minBound), (hi, maxBound))) hi (H.singleton (0, (0, 0), U))
      where
        (lo, hi) = bounds g
        emptyGrid = flip listArray (repeat maxBound)
    
    part1, part2 :: Grid -> Maybe Int
    part1 = (`solve` [1 .. 3])
    part2 = (`solve` [4 .. 10])
    
  • Leo Uino@lemmy.sdf.org
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    11 months ago

    Haskell

    Wowee, I took some wrong turns solving today’s puzzle! After fixing some really inefficient pruning I ended up with a Dijkstra search that runs in 2.971s (for a less-than-impressive 124.782 l-s).

    Solution
    import Control.Monad
    import Data.Array.Unboxed (UArray)
    import qualified Data.Array.Unboxed as Array
    import Data.Char
    import qualified Data.HashSet as Set
    import qualified Data.PQueue.Prio.Min as PQ
    
    readInput :: String -> UArray (Int, Int) Int
    readInput s =
      let rows = lines s
       in Array.amap digitToInt
            . Array.listArray ((1, 1), (length rows, length $ head rows))
            $ concat rows
    
    walk :: (Int, Int) -> UArray (Int, Int) Int -> Int
    walk (minStraight, maxStraight) grid = go Set.empty initPaths
      where
        initPaths = PQ.fromList [(0, ((1, 1), (d, 0))) | d <- [(0, 1), (1, 0)]]
        goal = snd $ Array.bounds grid
        go done paths =
          case PQ.minViewWithKey paths of
            Nothing -> error "no route"
            Just ((n, (p@(y, x), hist@((dy, dx), k))), rest)
              | p == goal && k >= minStraight -> n
              | (p, hist) `Set.member` done -> go done rest
              | otherwise ->
                  let next = do
                        h'@((dy', dx'), _) <-
                          join
                            [ guard (k >= minStraight) >> [((dx, dy), 1), ((-dx, -dy), 1)],
                              guard (k < maxStraight) >> [((dy, dx), k + 1)]
                            ]
                        let p' = (y + dy', x + dx')
                        guard $ Array.inRange (Array.bounds grid) p'
                        return (n + grid Array.! p', (p', h'))
                   in go (Set.insert (p, hist) done) $
                        (PQ.union rest . PQ.fromList) next
    
    main = do
      input <- readInput <$> readFile "input17"
      print $ walk (0, 3) input
      print $ walk (4, 10) input
    

    (edited for readability)

  • sjmulder@lemmy.sdf.org
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    11 months ago

    C

    Very not pretty and not efficient. Using what I think is dynamic programming - essentially I just propagate cost total through a (x, y, heading, steps in heading) state space, so every cell in that N-dimensional array holds the minimum total cost known to get to that state which is updated iteratively from the neighbours until it settles down.

    Debugging was annoying because terminals aren’t great at showing 4D grids. My mistakes were in the initial situation and missing the “4 steps to come to a stop at the end” aspect in part 2.

    https://github.com/sjmulder/aoc/blob/master/2023/c/day17.c

  • cacheson@kbin.social
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    11 months ago

    Nim

    Another tough one. Judging by the relative lack of comments here, I wasn’t the only one that had trouble. For me this one was less frustrating and more interesting than day 12, though.

    I solved part 1 by doing a recursive depth-first search, biasing towards a zigzag path directly to the goal in order to establish a baseline path cost. Path branches that got more expensive than the current best path terminated early. I also stored direction, speed, and heat loss data for each tile entered. Any path branch that entered a tile in the same direction and at the same (or greater) speed as a previous path was terminated, unless it had a lower temperature loss.

    This ran pretty slowly, taking around an hour to finish. I took a break and just let it run. Once it completed, it had gotten pretty late, so I did a quick naive modification for part 2 to account for the new movement restrictions, and let that run overnight. The next day it was still running, so I spent some time trying to think of a way to speed it up. Didn’t really get anywhere on my own, so I started reading up on A* to refresh my memory on how it worked.

    The solution that I arrived at for the rewrite was to use Dijkstra’s algorithm to pre-compute a map of what the minimum possible costs would be from each tile to the goal, if adjacent tiles could be moved to without restriction. I then used that as the heuristic for A*. While I was writing this, the original part 2 program did finish and gave the correct answer. Since I was already this far in though, I figured I’d finish the rewrite anyway.

    The new program got the wrong answer, but did so very quickly. It turned out that I had a bug in my Dijkstra map. I was sorting the node queue by the currently computed cost to move from that node to the goal, when it instead should have been sorted by that plus the cost to enter that node from a neighbor. Since the node at the head of the queue is removed and marked as finalized on each iteration, some nodes were being finalized before their actual minimum costs were found.

    When using the A* algorithm, you usually want your heuristic cost estimate to underestimate the actual cost to reach the goal from a given node. If it overestimates instead, the algorithm will overlook routes that are potentially more optimal than the computed route. This can be useful if you want to find a “good enough” route quickly, but in this case we need the actual best path.