Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I want to create my own monad. This is what i wrote:

data LeafConType a = LeafCon (a,Int,Int)

instance Monad (LeafConType ) where
return = LeafCon 
lc@(LeafCon (t,i,n)) >>= f = if i>=n
                                then lc
                                else f (t,i,n)

But this dont work. Ghc says:

leafcon.hs:26:1:
    Occurs check: cannot construct the infinite type: a = (a, Int, Int)
    When generalising the type(s) for `return'
    In the instance declaration for `Monad LeafConType'

leafcon.hs:27:1:
    Occurs check: cannot construct the infinite type: a = (a, Int, Int)
    When generalising the type(s) for `>>='
    In the instance declaration for `Monad LeafConType'

Whats wrong with that?


I want to do calculations while i is lower than n. n should be constants by I don't know yet how to do this correct. It should be some mix of State and Maybe. If you have some advices feel free to share it with me:P

share|improve this question

3 Answers 3

up vote 9 down vote accepted

About return:

Prelude> :t return
return :: (Monad m) => a -> m a

So return takes an argument of type a, and returns something of type m a. In this case m is LeafConType, so LeafConType a is returned.

Now suppose that we pass True. Then a = Bool, so the return type must be LeafConType Bool. However, you define:

return = LeafCon

So, return True becomes LeafCon True. But that is not allowed, because the type definition of LeafConType states that

data LeafConType a = LeafCon (a, Int, Int)

So for LeafConType Bool the argument to LeafCon must have type (Bool, Int, Int), not just Bool. And that is what the compile error means: a cannot be the same as (a, Int, Int). You state:

I want to do calculations while i is lower than n.

This means that you will need some default values for i and n, for otherwise it will be impossible to define return. If both of them are zero by default, then you could define:

return a = LeafCon (a, 0, 0)

About (>>=):

Prelude> :t (>>=)
(>>=) :: (Monad m) => m a -> (a -> m b) -> m b

Now look at your implementation (slightly different notation, same idea):

lc@(LeafCon (t, i, n)) >>= f | i >= n    = lc 
                             | otherwise = f t

What we see here, is that lc is returned when i >= n. But lc is of type LeafConType a, while f is a function which may return a value of type LeafConType b, for any b. As a result it could be that b is not equal to a and hence these types don't match. In conclusion, you seriously have to ask yourself one question:

  Can this type of computation be expressed as a monad anyway?

share|improve this answer
    
I think it can, maybe not this way, but its possible. It should carry information like State monad, and end calculations like Maybe monad. –  qba Nov 22 '09 at 20:39
    
Have you considered using a state transformer? en.wikibooks.org/wiki/Haskell/Monad_transformers. Have a look at StateT and ErrorT. –  Stephan202 Nov 22 '09 at 21:04
    
and don't forget the MaybeT –  barkmadley Nov 23 '09 at 9:57

The functions you specified for >>= and return don't satisfy the types required by Monad:

return :: a -> LeafConType a

Given the declaration

return = LeafCon

you give the function the incompatible type

return :: (a, Int, Int) -> LeafConType a

A statement like return 42 would therefore be impossible in your monad.

I don't understand what your monad should do at all. First take a look at simple, working monads!

instance Monad [] where
    (>>=) = concatMap
    return a = [a]

instance Monad Maybe where
    return = Just
    (Just x) >>= f = f x
    Nothing >>= f = Nothing
share|improve this answer
    
I should have pressed that button 10 seconds sooner... ;) –  Stephan202 Nov 22 '09 at 18:18

Judging from your description of what you want your monad to do, I think you want something a bit like this:

data LeafConType a = LeafCon { runLeafCon' :: Int -> Int -> (Maybe a, Int, Int) }

runLeafCon :: Int -> Int -> LeafConType a -> Maybe a
runLeafCon i n lc = let (t, _, _) = runLeafCon' lc i n in t

getI :: LeafConType Int
getI = LeafCon $ \i n -> (Just i, i, n)

getN :: LeafConType Int
getN = LeafCon $ \i n -> (Just n, i, n)

setI :: Int -> LeafConType ()
setI i = LeafCon $ \_ n -> (Just (), i, n)

setN :: Int -> LeafConType ()
setN n = LeafCon $ \i _ -> (Just (), i, n)

instance Monad LeafConType where
    return t = LeafCon $ \i n -> if (i < n) 
                                 then (Just t, i, n) 
                                 else (Nothing, i, n)

    (LeafCon k) >>= f = 
        LeafCon $ \i n -> 
            let (t, i', n') = k i n
            in case t of
                 Nothing -> (Nothing, i', n')
                 (Just t') -> if (i' < n')
                              then runLeafCon' (f t') i' n'
                              else (Nothing, i, n)


example :: Int -> LeafConType ((), Int)
example x = do 
  i <- getI
  m <- setI (i + x)
  return (m, i + x)

Some examples:

*Main> runLeafCon 2 10 $ example 4
Just ((),6)
*Main> runLeafCon 2 10 $ example 8
Nothing
*Main> runLeafCon 2 10 $ example 7
Just ((),9)

I threw this together pretty quickly, it's rather ugly, and I haven't checked to see whether it obeys any of the Monad laws, so use at your peril! :)

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.