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I'm working on a lab in which we work with randomness and monads.

The parts of the lab are:

  1. write a function randR that generates a random numbers within a given range
  2. write a function rollTwoDice that simulates rolling two dice
  3. write a function removeCard which randomly removes a card from a list of PlayingCards
  4. write a function shuffleDeck which takes the removed card, puts it in front of the deck, then repeats itself until the deck has been completely shuffled.

I have done 1, 2, and 3, but I'm having trouble with 4.

Here's the given code:

RandState.hs

module RandState where
import UCState
import System.Random

-- In order to generate pseudo-random numbers, need to pass around generator
--  state in State monad
type RandState a = State StdGen a

-- runRandom runs a RandState monad, given an initial random number generator
runRandom :: RandState a -> StdGen -> a
runRandom (State f) s = res
    where (res, state) = f s

-- rand is a helper function that generates a random instance of any
--  type in the Random class, using the RandState monad.
rand :: Random a => RandState a
rand = do
    gen <- get
    let (x, gen') = random gen
    put gen'
    return x

UCState.hs

{- 
 - Simplified implementation of the State monad.  The real implementation
 - is in the Control.Monad.State module: using that is recommended for real 
 - programs.
 -}
module UCState where

data State s a = State { runState :: s -> (a, s) }

instance Monad (State s)
    where
        {-
         - return lifts a function x up into the state monad, turning it into
         -  a state function that just passes through the state it receives
         -}
        return x = State ( \s -> (x, s) )

        {- 
         - The >>= combinator combines two functions p and f, and 
         -  gives back a new function (Note: p is originally wrapped in the 
         -  State monad)
         -
         - p: a function that takes the initial state (from right at the start
         - of the monad chain), and gives back a new state and value, 
         - corresponding to the result of the chain up until this >>=
         - f: a function representing the rest of the chain of >>='s
         -}
        (State p) >>= f = State ( \initState -> 
                                  let (res, newState) = p initState
                                      (State g) = f res
                                  in g newState )

-- Get the state
get :: State s s  
get = State ( \s -> (s, s) )

-- Update the state
put :: s -> State s ()
put s = State ( \_ -> ((), s))

Here's my code, which I just wrote inside RandState.hs since I couldn't figure out how to import it (help with importing would be nice as well, although not what I'm most concerned about at this point):

randR :: Random a => (a, a) -> RandState a
randR (lo, hi) = do
    gen <- get
    let (x, gen') = randomR (lo, hi) gen
    put gen'
    return x

testRandR1 :: IO Bool
testRandR1 = do
    gen <- newStdGen
    let genR = runRandom (randR (1,5)) gen :: Int
    return (genR <=5 && genR >=1)

testRandR2 :: IO Bool
testRandR2 = do
    gen <- newStdGen
    let genR = runRandom (randR (10.0, 11.5)) gen :: Double
    return (genR <= 11.5 && genR >= 10.0)

rollTwoDice :: RandState Int
rollTwoDice = do
    gen <- get
    let (a, gen') = randomR (1, 6) gen :: (Int, StdGen)
    put gen'
    let (b, gen'') = randomR (1, 6) gen' :: (Int, StdGen)
    put gen''
    return $ a + b

testRollTwoDice :: IO Bool
testRollTwoDice = do
    gen <- newStdGen
    let genR = runRandom (rollTwoDice) gen
    return (genR <= 12 && genR >= 2)

-- Data types to represent playing cards
data CardValue = King | Queen | Jack | NumberCard Int
    deriving (Show, Eq)
data CardSuit = Hearts | Diamonds | Spades | Clubs
    deriving (Show, Eq)
data PlayingCard = PlayingCard CardSuit CardValue
    deriving (Show, Eq)

{-
 - fullCardDeck will be a deck of cards, 52 in total, with a King, a Queen, 
 - a Jack and NumberCards from 1 to 10 for each suit.
 -}
-- fullCardDeck and its definition were given in the lab
fullCardDeck :: [PlayingCard]
fullCardDeck = [ PlayingCard s v | s <- allsuits, v <- allvals ] where
        allvals = King : Queen : Jack : [ NumberCard i | i <- [1..10] ]
        allsuits = [Hearts, Diamonds, Spades, Clubs]

removeCard :: [a] -> RandState [a]
removeCard deck = do
    gen <- get
    let n = runRandom (randR(1, length (deck))) gen :: Int
    let (xs, ys) = splitAt (n-1) deck
    return $ head ys : xs ++ tail ys

shuffleDeck deck = do
    gen <- get
    let f deck = head $ runRandom (removeCard deck) gen
    return $ take (length(deck)) (iterate f deck)

shuffleDeck doesn't work. The error:

RandState.hs:88:31:
    Occurs check: cannot construct the infinite type: a0 = [a0]
    Expected type: [a0] -> [a0]
      Actual type: [a0] -> a0
    In the first argument of `iterate', namely `f'
    In the second argument of `take', namely `(iterate f deck)'
    In the second argument of `($)', namely `take 52 (iterate f deck)'

I guess the issue is that iterate takes a value, applies a function to this value, applies the function to the result, and so on, returning an infinite list of results. I'm handing iterate a function that takes a list, and returns a card, so the result cannot be passed to the next iteration. What would be a better way to approach this problem (4)? I'm also worried that my removeCard function is a little janky since it just puts the "removed" card in front, which I did to make shuffleDeck easier to write. If necessary, what would be a better way to approach this problem (3)?

Thanks, Jeff

share|improve this question
    
my best guest is take out 'head $' from f, as you want to iterate over the whole deck (and not over the first card!). It should at least typecheck. edit: yeah that's the way, you'll have to fix the take argument, but you should be able to figure it out. –  MdxBhmt Nov 14 '13 at 0:56
    
import should import things :) –  jozefg Nov 14 '13 at 1:38
    
Thanks MdxBhmt, I removed head $ from f, then mapped head to the iterated list. I can't get shuffleDeck to display its results though, apparently because there is no instance of (Show (RandState [PlayingCard])). Any ideas for that? And jozefg, I already tried doing import last night and it didn't work, but I just tried it again now and it worked. Maybe your comment was the x factor, so thanks. –  Jeff Nov 14 '13 at 1:52
    
@user2967411 You can't print a RandState since it's a function, you'll have to runRandom and print the result –  jozefg Nov 14 '13 at 1:53

1 Answer 1

up vote 1 down vote accepted

You should stop trying to runRandom inside your functions. You should only use runRandom once you actually want a result (for example - to print the result, since you can't do this inside the monad). Trying to 'escape' from the monad is a futile task and you will only produce confusing and often non-functioning code. The final output of all of your functions will be inside the monad, so you don't need to escape anyways.

Note that

gen <- get
let n = runRandom (randR(1, length (deck))) gen :: Int

is exactly equivalent to

n <- randR (1, length deck)

The <- syntax executes a computation in monad on the right and 'puts' it into the variable name on the left.

Shuffling:

shuffleR [] = return []   
shuffleR xs = do      
  (y:ys) <- removeR xs  -- 1
  zs <- shuffleR ys     -- 2
  return (y:zs)         -- 3

The function is straightforward recursion: 1) extract a random element, 2) shuffle what is left, 3) combine the results.

edit: extra info requested:

randSum :: (Num b, Random b) => State StdGen b
randSum = do
  a <- randR (1,6) 
  b <- randR (1,6) 
  return $ a + b

compiles just fine. Judging from your description of the error, you are trying to call this function inside the IO monad. You cannot mix monads (or at least not so simply). If you want to 'execute' something of type RandState inside of IO you will indeed have to use runRandom here.

n <- randR (1, length deck) makes n an Int because length deck has type Int and randR :: Random a => (a, a) -> RandState a, so from the context we can infer a ~ Int and the type unifies to (Int, Int) -> RandState Int.

Just to recap

Wrong:

try = do
  a <- randomIO      :: IO Int
  b <- randR (0,10)  :: RandState Int
  return $ a + b     -- monads don't match!

Right:

try = do
  a <- randomIO                                 :: IO Int
  let b = runRandom (randR (0,10)) (mkStdGen a) :: Int    -- 'execute' the randstate monad
  return $ a + b          
share|improve this answer
    
Thank you so much! That made a lot of sense. Now I have a question on rollTwoDice though. I went back and saw that the problem requires me to use randR in my implementation. So I hoped that I could just write a <- randR (1,6) // b <- randR (1,6) // return $ a + b but this won't compile. I'm a bit confused about how n <- randR (1, length deck) successfully made n an integer (at least that's how I understood it), but adding a <- randR (1,6) with b <- randR (1,6) doesn't just give me the sum of a and b. The function expects type IO t0 but I am apparently giving it type RandState Integer. –  Jeff Nov 14 '13 at 3:29
1  
Updated answer with reply. –  user2407038 Nov 14 '13 at 3:45

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