this post was submitted on 04 Dec 2023
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Advent Of Code

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submitted 11 months ago* (last edited 11 months ago) by Ategon to c/advent_of_code
 

Day 4: Scratchcards


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[–] [email protected] 1 points 11 months ago

[Language: Lean4]

I'll only post the actual parsing and solution. I have written some helpers which are in other files, as is the main function. For the full code, please see my github repo.

I'm pretty sure that implementing part 2 in a naive way would cause Lean to demand a proof of termination, what might not be that easy to supply in this case... Luckily there's a way more elegant and way faster solution than the naive one, that can use structural recursion and therefore doesn't need an extra proof of termination.

Solution

structure Card where
  id : Nat
  winningNumbers : List Nat
  haveNumbers : List Nat
  deriving Repr

private def Card.matches (c : Card) : Nat :=
  flip c.haveNumbers.foldl 0 λo n ↦
    if c.winningNumbers.contains n then o + 1 else o

private def Card.score : Card → Nat :=
  (· / 2) ∘ (2^·) ∘ Card.matches

abbrev Deck := List Card

private def Deck.score : Deck → Nat :=
  List.foldl (· + ·.score) 0

def parse (input : String) : Option Deck := do
  let mut cards : Deck := []
  for line in input.splitOn "\n" do
    if line.isEmpty then
      continue
    let cs := line.splitOn ":"
    if p : cs.length = 2 then
      let f := String.trim $ cs[0]'(by simp[p])
      let g := String.trim $ cs[1]'(by simp[p])
      if not $ f.startsWith "Card " then
        failure
      let f := f.drop 5 |> String.trim
      let f ← f.toNat?
      let g := g.splitOn "|"
      if q : g.length = 2 then
        let winners := String.trim $ g[0]'(by simp[q])
        let draws := String.trim $ g[1]'(by simp[q])
        let toNumbers := λ(s : String) ↦
          s.split (·.isWhitespace)
          |> List.filter (not ∘ String.isEmpty)
          |> List.mapM String.toNat?
        let winners ← toNumbers winners
        let draws ← toNumbers draws
        cards := {id := f, winningNumbers := winners, haveNumbers := draws : Card} :: cards
      else
        failure
    else
      failure
  return cards -- cards is **reversed**, that's intentional. It doesn't affect part 1, but makes part 2 easier.

def part1 : Deck → Nat := Deck.score

def part2 (input : Deck) : Nat :=
  -- Okay, doing this brute-force is dumb.
  -- Instead let's compute how many cards each original card is worth, and sum that up.
  -- This relies on parse outputting the cards in **reverse** order.
  let multipliers := input.map Card.matches
  let sumNextN : Nat → List Nat → Nat := λn l ↦ (l.take n).foldl (· + ·) 0
  let rec helper : List Nat → List Nat → List Nat := λ input output ↦ match input with
    | [] => output
    | a :: as => helper as $ (1 + (sumNextN a output)) :: output
  let worths := helper multipliers []
  worths.foldl (· + ·) 0