I am attempting to create a game of Paper Scissors Stone using Haskell to practice my understanding of it.
Unfortunately, the source code below gives unwanted answers.
>play pStone pRandom 1 1 games were played. Player 1 won 1 and player 2 won 1, making the match a draw.
If 1 game is played, there should only be either 1 or 0 wins.
>play pStone pCopy 100 100 games were played. Player 1 won 1 and player 2 won 1, making the match a draw.
If 100 games are played, where (after the first round) both play the same move, there should only be either 1 or 0 wins.
>play pCopy pAntiCopy 100 100 games were played. Player 1 won 31 and player 2 won 37, making player 2 the overall winner.
By the intended definitions of pCopy and pAntiCopy, pAntiCopy should win either 99 or 100 and pCopy should win 0 or 1.
I believe the most likely reason for this behaviour is that the random numbers are evaluated at the end, meaning that 2 values which are supposed to rely upon the same random number instead rely on 2 separate random numbers. Am I correct in the above?
If I am correct, please could you advise me on how I should correct this? If I am incorrect, please could you tell me what the problem is and how it should be resolved?
I have read a solution to a separate problem which suggests generating a list of random numbers and then using them, passing them as arguments to the relevant functions from a main function. I do not believe this would work that well here, though, as the number of random numbers needed could be anything from 0 to 2*numRounds, dependent on the plans being used (I intend to create more advanced plans when this is working) and the readability of the code would further decrease.
I am new to Haskell and functional programming in general, so I apologise for the style of the source code below. If you have any suggestions on how it could be improved, they are also most welcome.
import System.Random data Move= Paper|Scissors|Stone deriving Show type Plan=([IO Move]->[IO Move]->IO Move) play :: Plan -> Plan -> Integer -> IO () play plan1 plan2 numRounds=do p1intwins<-p1wins;p2intwins<-p2wins;putStr(show numRounds ++ " games were played. Player 1 won " ++ show p1intwins ++ " and player 2 won " ++ show p2intwins ++ ", making " ++ (if p1intwins > p2intwins then "player 1 the overall winner." else (if p1intwins < p2intwins then "player 2 the overall winner." else "the match a draw."))) where (_, _, _, _, _, _, p1wins, p2wins)=(playRound (plan1, plan2, numRounds,,, 0, return 0, return 0)) playRound :: (Plan, Plan, Integer, [IO Move], [IO Move], Integer, IO Integer, IO Integer) -> (Plan, Plan, Integer, [IO Move], [IO Move], Integer, IO Integer, IO Integer) playRound (plan1, plan2, numRounds, p1moves, p2moves, elapsedRounds, p1wins, p2wins)=if elapsedRounds==numRounds then (plan1, plan2, numRounds, p1moves, p2moves, elapsedRounds, p1wins, p2wins) else (playRound (plan1, plan2, numRounds, p1moves++[p1move], p2moves++[p2move], elapsedRounds+1, do p1win<-beatsCaller p1move p2move;p1intwins<-p1wins;return (p1intwins+if p1win then 1 else 0), do p2win<-beatsCaller p2move p1move;p2intwins<-p2wins;return(p2intwins+(if p2win then 1 else 0)) )) where p1move=plan1 p1moves p2moves; p2move=plan2 p2moves p1moves beatsCaller :: IO Move -> IO Move -> IO Bool beatsCaller iom1 iom2=do m1<-iom1;m2<-iom2;return(beats m1 m2) beats :: Move -> Move -> Bool beats Scissors Paper=True beats Stone Scissors=True beats Paper Stone=True beats _ _=False -- ###############Plans################### pStone :: Plan pStone _ _ = return Stone pScissors :: Plan pScissors _ _ = return Scissors pPaper :: Plan pPaper _ _ = return Paper pUScissors :: Plan pUScissors  _ = randomMove pUScissors _ _ = return Scissors pCopy :: Plan pCopy _ = randomMove pCopy _ theirMoves= last theirMoves pRandom :: Plan pRandom _ _=randomMove pAntiCopy :: Plan pAntiCopy  _ = randomMove pAntiCopy ourMoves _ = do ourMove<-last ourMoves;return(beaterOf ourMove) -- ##############Plan Logic############### beaterOf :: Move -> Move beaterOf Scissors = Stone beaterOf Paper = Scissors beaterOf Stone = Paper randomMove :: IO Move randomMove=do x<-genRandom;return (doRMove x) doRMove:: Int -> Move doRMove rand |rand==1 =Paper |rand==2 =Scissors |rand==3 =Stone genRandom :: IO Int genRandom =getStdRandom (randomR (1,3))