I'm working on a lab in which we work with randomness and monads.
The parts of the lab are:
 write a function randR that generates a random numbers within a given range
 write a function rollTwoDice that simulates rolling two dice
 write a function removeCard which randomly removes a card from a list of PlayingCards
 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 pseudorandom 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 (n1) 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
import
should import things :) – jozefg Nov 14 '13 at 1:38runRandom
and print the result – jozefg Nov 14 '13 at 1:53