Day 13 (dirty)

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Martin Potier 2020-12-21 15:27:51 +02:00
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@ -1,6 +1,6 @@
#! /usr/bin/env -S"GHCRTS=-N4" nix-shell #! /usr/bin/env -S"GHCRTS=-N4" nix-shell
#! nix-shell -p ghcid #! nix-shell -p ghcid
#! nix-shell -p "haskellPackages.ghcWithPackages (p: with p; [pretty-simple attoparsec arithmoi containers parallel])" #! nix-shell -p "haskellPackages.ghcWithPackages (p: with p; [pretty-simple attoparsec arithmoi containers parallel semirings])"
#! nix-shell -i "ghcid -c 'ghci' -T main" #! nix-shell -i "ghcid -c 'ghci' -T main"
{-# OPTIONS_GHC -Wall -Wincomplete-uni-patterns #-} {-# OPTIONS_GHC -Wall -Wincomplete-uni-patterns #-}
@ -11,23 +11,24 @@
{-# LANGUAGE DataKinds #-} {-# LANGUAGE DataKinds #-}
import Control.Applicative import Control.Applicative
import Control.Monad
import Control.Parallel.Strategies (parMap, parListChunk, rdeepseq)
import Data.Attoparsec.Text (Parser) import Data.Attoparsec.Text (Parser)
import Data.Euclidean (gcdExt)
import Data.IntSet (IntSet) import Data.IntSet (IntSet)
import Data.List (find,sortOn,sort) import Data.List (find,sortOn,sort)
import Data.Maybe (fromMaybe,catMaybes) import Data.Maybe (fromMaybe,catMaybes)
import Data.Monoid import Data.Monoid
import Data.Text (Text) import Data.Text (Text)
import Data.Vector (Vector) import Data.Vector (Vector)
import Debug.Trace (trace,traceShowId) import Debug.Trace (trace,traceShow,traceShowId)
import Math.NumberTheory.ArithmeticFunctions import Math.NumberTheory.ArithmeticFunctions
import Math.NumberTheory.Primes import Math.NumberTheory.Primes
--import Math.NumberTheory.Moduli.Class
import Text.Pretty.Simple import Text.Pretty.Simple
import qualified Data.Attoparsec.Text as A import qualified Data.Attoparsec.Text as A
import qualified Data.IntSet as I import qualified Data.IntSet as I
import qualified Data.Text as T import qualified Data.Text as T
import qualified Data.Vector as V import qualified Data.Vector as V
import Control.Parallel.Strategies (parMap, parListChunk, rdeepseq)
exampleData :: String exampleData :: String
exampleData = "939\n7,13,x,x,59,x,31,19" exampleData = "939\n7,13,x,x,59,x,31,19"
@ -97,7 +98,7 @@ findAllEq = find (\xs -> notElem (head xs) xs)
isT :: Int -> Int -> [(Int,Int)] -> Int isT :: Int -> Int -> [(Int,Int)] -> Int
isT tpx x xs = head $ catMaybes $ map go allTs isT tpx x xs = head $ catMaybes $ map go allTs
where where
allTs = [158478605388*tpx,158478605389*tpx..] allTs = [tpx,2*tpx..]
go :: Int -> Maybe Int go :: Int -> Maybe Int
go tpx0 = case and (parMap rdeepseq (go' tpx0) xs) of go tpx0 = case and (parMap rdeepseq (go' tpx0) xs) of
True -> Just (tpx0 - x) True -> Just (tpx0 - x)
@ -106,15 +107,76 @@ isT tpx x xs = head $ catMaybes $ map go allTs
-- trace ("tpx:"<>show tpx0'<>",shift:"<>show shift<>",x:"<>show x<>",fact:"<>show fact) $ -- trace ("tpx:"<>show tpx0'<>",shift:"<>show shift<>",x:"<>show x<>",fact:"<>show fact) $
(tpx0' - x + shift) `mod` fact == 0 (tpx0' - x + shift) `mod` fact == 0
solvePart2 :: String -> Either String Int solvePart2Naive :: String -> Either String Int
solvePart2 str = do solvePart2Naive str = do
(_,xs) <- parseInput2 str (_,xs) <- parseInput2 str
let startAndIds = catMaybes $ sequence <$> zip [0..] xs let startAndIds = traceShowId $ catMaybes $ sequence <$> zip [0..] xs
let sortedStartAndIds = traceShowId $ reverse $ sortOn snd $ startAndIds let sortedStartAndIds = reverse $ sortOn snd $ startAndIds
-- pure $ sortedStartAndIds -- pure $ sortedStartAndIds
let (x,t) = head sortedStartAndIds let (x,t) = head sortedStartAndIds
pure $ isT t x sortedStartAndIds pure $ isT t x sortedStartAndIds
-- -------------------------------------------------------------------------- --
-- Here I sneak around a bit, and realize the problem is well defined --
-- (and solved!) already: it's called the Chinese Remainder Theorem --
-- https://en.wikipedia.org/wiki/Chinese_remainder_theorem --
-- -------------------------------------------------------------------------- --
-- Apllying the theorem allows to reduce a system of equation on x: --
-- --
-- x ≡ a1 (mod n1) --
-- · --
-- · --
-- · --
-- x ≡ ak (mod nk) --
-- --
-- to a single equation: --
-- --
-- x ≡ as (mod ns) --
-- --
-- It relates to the buses schedules in the following way: t is x, the bus --
-- number is the modulo factor (since a bus comes *every* ni) and subsequent --
-- additions to t (for other buses) is (-ai), so, for a but coming at --
-- t+ai, one would write x ≡ -ai (mod ni) --
-- --
-- I chose to encode ai and ni as a tuple (ai,ni), named startAndIds --
-- --
-- Basically, we're creating a “chinese” function: --
-- --
-- chinese :: (Int,Int) -> (Int,Int) -> (Int,Int) --
-- --
-- Then, given a list [(Int, Int)] we can fold over it to obtain the solution --
-- --
chinese :: (Integer,Integer) -> (Integer,Integer) -> Maybe (Integer,Integer)
chinese (0,n1) (0,n2) = chinese (n1,n1) (n2,n2)
chinese v (0,n2) = chinese v (n2,n2)
chinese (0,n1) v = chinese (n1,n1) v
chinese (a1,n1) (a2,n2) = do
-- Computes a solution such that: n1×c1 + n2×c2 = g, for some c2
-- n1×c1 - g = - n2×c2, for some c2
-- 1/n2 (n1×c1 - g) = - c2, for some c2 (n2 is > 0)
-- - 1/n2 (n1×c1 - g) = c2, for some c2 (n2 is > 0)
-- n1 and n2 must be coprimes for this to work (g must be 1), fail otherwise
(m1,m2) <- case gcdExt n1 n2 of
(1,c1) -> Just ( c1, negate ((n1 * c1) - 1) `div` n2 )
_ -> Nothing
let x = a1 * m2 * n2 + a2 * m1 * n1
let a12 = x `mod` (n1 * n2)
pure $ (a12, n1 * n2)
e2m :: Either e a -> Maybe a
e2m (Right v) = Just v
e2m _ = Nothing
solvePart2Clever :: String -> Maybe (Integer,Integer)
solvePart2Clever str = do
(_,xs) <- e2m $ parseInput2 str
let startAndIds = catMaybes $ sequence <$> zip [0..] (map (fmap fromIntegral) xs)
let chineseEqs = traceShowId $ fmap (\(a,n) -> ((-a) `mod` n, n)) startAndIds
foldM chinese (1,1) chineseEqs
main :: IO () main :: IO ()
main = do main = do
putStrLn ":: Test" putStrLn ":: Test"
@ -146,11 +208,20 @@ main = do
print $ 100000000000000 `mod` 631 print $ 100000000000000 `mod` 631
print $ 100000000000000 `div` 631 print $ 100000000000000 `div` 631
putStrLn ":: Day 13 - Part 2" putStrLn ":: Day 13 - Part 2"
print $ solvePart2 "939\n3,5" print $ solvePart2Naive exampleData
print $ solvePart2 exampleData print $ solvePart2Naive "1\n17,x,13,19"
print $ solvePart2 "1\n17,x,13,19" print $ solvePart2Naive "1\n67,7,59,61"
print $ solvePart2 "1\n67,7,59,61" print $ solvePart2Naive "1\n67,x,7,59,61"
print $ solvePart2 "1\n67,x,7,59,61" print $ solvePart2Naive "1\n67,7,x,59,61"
print $ solvePart2 "1\n67,7,x,59,61" print $ solvePart2Naive "1\n1789,37,47,1889"
print $ solvePart2 "1\n1789,37,47,1889" putStrLn ""
print $ solvePart2 input print $ solvePart2Clever exampleData
print $ solvePart2Clever "1\n17,x,13,19"
print $ solvePart2Clever "1\n67,7,59,61"
print $ solvePart2Clever "1\n67,x,7,59,61"
print $ solvePart2Clever "1\n67,7,x,59,61"
print $ solvePart2Clever "1\n1789,37,47,1889"
putStrLn ""
-- Don't, it just takes forever.
-- print $ solvePart2Naive input
print $ solvePart2Clever input