+-- Some code taken from [AoC 2017 day 5](https://adventofcode.com/2017/day/5),
+-- and some from [AoC 2018 day 21](https://adventofcode.com/2018/day/21)
+
+import Data.Text (Text)
+import qualified Data.Text.IO as TIO
+
+import Data.Void (Void)
+
+import Text.Megaparsec hiding (State)
+import Text.Megaparsec.Char
+import qualified Text.Megaparsec.Char.Lexer as L
+import qualified Control.Applicative as CA
+
+import Control.Monad (unless)
+import Control.Monad.State.Strict
+
+import qualified Data.IntMap.Strict as M
+import Data.IntMap.Strict ((!))
+
+type Memory = M.IntMap Int
+
+data Machine = Machine { _memory :: Memory
+ , _ip :: Int
+ }
+ deriving (Show, Eq)
+
+type ProgrammedMachine = State Machine ()
+
+
+main :: IO ()
+main = do
+ text <- TIO.readFile "data/advent02.txt"
+ let mem = successfulParse text
+ let machine = makeMachine mem
+ print $ part1 machine
+ print $ part2 machine
+
+
+-- part1 machine = (_memory $ execState runAll machine1202)!0
+-- where machine1202 = machine { _memory = M.insert 1 12 $ M.insert 2 2 $ _memory machine }
+
+
+part1 = nounVerbResult 12 2
+
+part2Target = 19690720
+
+part2 machine = noun * 100 + verb
+ where (noun, verb) = head $ [(n, v) | n <- [0..99], v <- [0..99],
+ nounVerbResult n v machine == part2Target ]
+
+
+makeMachine :: [Int] -> Machine
+makeMachine memory = Machine {_ip = 0, _memory = M.fromList $ zip [0..] memory}
+
+nounVerbResult :: Int -> Int -> Machine -> Int
+nounVerbResult noun verb machine = machineOutput nvMachine
+ where nvMachine0 = machineNounVerb machine noun verb
+ nvMachine = execState runAll nvMachine0
+
+machineNounVerb :: Machine -> Int -> Int -> Machine
+machineNounVerb machine noun verb = machine { _memory = M.insert 1 noun $ M.insert 2 verb $ _memory machine }
+
+machineOutput :: Machine -> Int
+machineOutput machine = (_memory machine)!0
+
+
+runAll :: ProgrammedMachine
+runAll = do m0 <- get
+ unless (lkup (_ip m0) (_memory m0) == 99)
+ do runStep
+ runAll
+
+runStep :: ProgrammedMachine
+runStep =
+ do m0 <- get
+ let mem = _memory m0
+ let ip = _ip m0
+ let (mem', ip') = perform (mem!ip) ip mem
+ put m0 {_ip = ip', _memory = mem'}
+
+perform :: Int -> Int -> Memory -> (Memory, Int)
+perform 1 ip mem = (iInsert (ip + 3) (a + b) mem, ip + 4)
+ where a = mem!>(ip + 1)
+ b = mem!>(ip + 2)
+perform 2 ip mem = (iInsert (ip + 3) (a * b) mem, ip + 4)
+ where a = mem!>(ip + 1)
+ b = mem!>(ip + 2)
+
+
+-- Some IntMap utility functions, for syntactic sugar
+
+-- prefix version of (!)
+lkup k m = m!k
+
+-- indirect lookup
+(!>) m k = m!(m!k)
+
+-- indirect insert
+iInsert k v m = M.insert (m!k) v m
+
+
+
+-- Parse the input file
+type Parser = Parsec Void Text
+
+sc :: Parser ()
+sc = L.space (skipSome spaceChar) CA.empty CA.empty
+-- sc = L.space (skipSome (char ' ')) CA.empty CA.empty
+
+lexeme = L.lexeme sc
+integer = lexeme L.decimal
+-- signedInteger = L.signed sc integer
+symb = L.symbol sc
+comma = symb ","
+
+memoryP = integer `sepBy` comma
+
+successfulParse :: Text -> [Int]
+successfulParse input =
+ case parse memoryP "input" input of
+ Left _err -> [] -- TIO.putStr $ T.pack $ parseErrorPretty err
+ Right memory -> memory
\ No newline at end of file