205 lines
6.5 KiB
Nim
205 lines
6.5 KiB
Nim
import ./common, std/[strutils, sugar, sequtils, options, tables, sets, strformat, algorithm]
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type
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Vec2 = tuple[x: int, y: int]
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AmphipodBreed = enum A, B, C, D
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Amphipod = tuple[breed: AmphipodBreed, pos: Vec2]
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AmphipodCaveState = seq[Amphipod]
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const HOMES = [2, 4, 6, 8]
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let homeSet = HOMES.toHashSet
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proc `$`(s: AmphipodCaveState): string =
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var ss = @["...........", " . . . .", " . . . .", ""]
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if s.len > 8:
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ss = @["...........", " . . . .", " . . . .", " . . . .", " . . . .", ""]
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for a in s:
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let bb = $a.breed
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ss[a.pos.y][a.pos.x] = bb[0]
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ss.join("\n")
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proc weight(b: AmphipodBreed): int = [1, 10, 100, 1000][b.ord]
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proc home(b: AmphipodBreed): int = HOMES[b.ord]
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proc newAmphipod(b: AmphipodBreed, x: int, y: int): Amphipod = (breed: b, pos: (x: x, y: y))
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proc parseAmphipodBreed(c: char): Option[AmphipodBreed] =
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case c:
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of 'A': some A
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of 'B': some B
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of 'C': some C
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of 'D': some D
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else: none AmphipodBreed
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proc v2(x: int, y: int): Vec2 = (x, y)
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proc parseCaveState(l: Lines): AmphipodCaveState =
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for y,s in l:
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for x,c in s:
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let b = c.parseAmphipodBreed
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if b.isSome: result.add newAmphipod(b.get, x - 1, y - 1)
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proc path(s: AmphipodCaveState, ai: int, goal: Vec2): seq[Vec2] =
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let a = s[ai]
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if a.pos.y > 0:
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for y in toSeq(0..<a.pos.y).reversed:
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result.add (x: a.pos.x, y: y)
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for x in min(a.pos.x, goal.x)..max(a.pos.x, goal.x):
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if x == a.pos.x: continue
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result.add (x: x, y: 0)
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if goal.y > 0:
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for y in 1..goal.y:
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result.add (x: goal.x, y: y)
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proc move(s: AmphipodCaveState, ai: int, p: Vec2): (AmphipodCaveState, uint64) =
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var newState = s
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newState[ai].pos = p
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(newState, s.path(ai, p).len.uint64 * s[ai].breed.weight.uint64)
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proc spaceOccupied(s: AmphipodCaveState, p: Vec2): bool =
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let maxY = if s.len > 8: 4 else: 2
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s.anyIt(it.pos == p) or (p.y > maxY or p.y < 0 or p.x < 0 or p.x > 10)
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proc canMoveTo(s: AmphipodCaveState, ai: int, goal: Vec2): bool =
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let a = s[ai]
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let pos = s[ai].pos
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# echo " -> staying in hallway"
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if pos.y == 0 and goal.y == 0: return false
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# echo " -> blocking homes"
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if goal.y == 0 and homeSet.contains(goal.x): return false
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# echo " -> out of bounds"
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if goal.y > 0 and not homeSet.contains(goal.x): return false
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# echo " -> not bottom of home"
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if goal.y >= 1:
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let maxY = if s.len > 8: 4 else: 2
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for y in goal.y+1..maxY:
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if not s.spaceOccupied(v2(goal.x, y)): return false
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# echo " -> not-yet-empty home"
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if goal.y > 0:
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for sib in s:
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if sib.breed == a.breed: continue
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if sib.pos.x == goal.x and sib.pos.y > goal.y: return false
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if goal.y > 0 and goal.x != a.breed.home: return false
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# echo " -> pathing blocked"
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let path = s.path(ai, goal)
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# echo path
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if path.anyIt(s.spaceOccupied(it)): return false
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true
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proc isWin(s: AmphipodCaveState): bool =
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result = s.allIt(it.pos.x == it.breed.home and it.pos.y > 0)
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# if result: echo &"WIN\n{s}\n"
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proc possibleMoves(s: AmphipodCaveState, ai: int): HashSet[Vec2] =
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let a = s[ai]
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if a.pos.y > 0:
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for x in 0..10:
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if not homeSet.contains x: result.incl v2(x, 0)
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let maxY = if s.len > 8: 4 else: 2
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for y in 1..maxY:
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result.incl (x: a.breed.home, y: y)
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proc getByPos(s: AmphipodCaveState, pos: Vec2): Option[Amphipod] = s.findFirstO(a => a.pos == pos)
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proc isHome(a: Amphipod): bool = a.pos.x == a.breed.home and a.pos.y > 0
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proc doneMoving(s: AmphipodCaveState, ai: int): bool =
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let maxY = if s.len > 8: 4 else: 2
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let a = s[ai]
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if a.isHome:
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if a.pos.y >= maxY: return true
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for y in (a.pos.y+1)..maxY:
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let below = s.getByPos((x: a.pos.x, y: y))
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if below.isSome:
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if below.get.breed != a.breed: return false
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else: return false
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return true
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false
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var cheapestWins = newTable[AmphipodCaveState, (uint64, uint64)]()
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proc cheapestWin(s: AmphipodCaveState, cost: uint64, depth = 0): uint64 =
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result = uint64.high
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# echo &"cheapestWin: {cost} {depth}\n{s}"
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if cheapestWins.hasKey s:
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if cheapestWins[s][0] <= cost:
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# echo &"cache hit for\n{s}\n -> {cheapestWins[s]}"
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return cheapestWins[s][1]
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if s.isWin or cost > 400000 or depth >= (s.len * 2): return cost
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var costs = initHashSet[uint64]()
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for ai,a in s:
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if s.doneMoving(ai): continue
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for p in s.possibleMoves ai:
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if not s.canMoveTo(ai, p): continue
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# echo &"Moving {ai} from {a.pos} to {p} at turn {depth}"
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let (newState, moveCost) = s.move(ai, p)
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costs.incl newState.cheapestWin(cost + moveCost, depth + 1)
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for c in costs: result = min(result, c)
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cheapestWins[s] = (cost, result)
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proc testMoves(state: AmphipodCaveState, moves: seq[(int, Vec2)]) =
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var s = state
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var cost: uint64 = 0
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for m in moves:
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echo s
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let (ai, goal) = m
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let doneMoving = s.doneMoving(ai)
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let suggestions = s.possibleMoves(ai)
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echo suggestions
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var sugs = @["...........", " . . . .", " . . . .", ""]
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if s.len > 8:
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sugs = @["...........", " . . . .", " . . . .", " . . . .", " . . . .", ""]
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for sug in suggestions:
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sugs[sug.y][sug.x] = 'X'
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sugs[s[ai].pos.y][s[ai].pos.x] = 'O'
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sugs[goal.y][goal.x] = '#'
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echo sugs.join("\n")
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let allowed = s.canMoveTo(ai, goal)
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let suggested = suggestions.contains goal
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echo &"Can move {ai} from {s[ai].pos} to {goal}: allowed: {allowed}, suggested: {suggested}, doneMoving: {doneMoving}"
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var (newState, moveCost) = s.move(ai, goal)
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cost += moveCost
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s = newState
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echo &"Did we win? {s.isWin} -- Cost so far: {cost}"
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proc p1(input: Lines): uint64 =
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echo "Crunching part 1"
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input.parseCaveState.cheapestWin(0)
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proc p2(input: Lines): uint64 =
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echo "Crunching part 2"
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var unfoldedInput = input
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unfoldedInput.insert(" #D#C#B#A#", 3)
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unfoldedInput.insert(" #D#B#A#C#", 4)
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echo unfoldedInput.parseCaveState
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unfoldedInput.parseCaveState.testMoves(@[
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(3, (x: 10, y: 0)),
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(7, (x: 0, y: 0)),
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(2, (x: 9, y: 0)),
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(6, (x: 7, y: 0)),
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(10, (x: 1, y: 0)),
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(1, (x: 6, y: 3)),
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(5, (x: 6, y: 2)),
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(9, (x: 5, y: 0)),
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(13, (x: 3, y: 0)),
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(9, (x: 4, y: 4)),
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(6, (x: 4, y: 3)),
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(2, (x: 4, y: 2)),
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(11, (x: 6, y: 1)),
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(15, (x: 9, y: 0)),
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(13, (x: 8, y: 4)),
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(0, (x: 4, y: 1)),
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(4, (x: 8, y: 3)),
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(8, (x: 8, y: 2)),
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(10, (x: 2, y: 3)),
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(7, (x: 2, y: 2)),
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(15, (x: 2, y: 1)),
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(3, (x: 8, y: 1)),
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])
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echo "Crunching part 2"
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unfoldedInput.parseCaveState.cheapestWin(0)
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const rt = ("""
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#############
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#...........#
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###B#C#B#D###
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#A#D#C#A#
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#########
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""".strip().split('\n'), 12521'u64, 44169'u64)
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doDayX 23, (n: int) => n.loadInput, p1, p2, rt
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