# Specializing bind for monads over special typeclasses in Haskell

In the second last chapter For a Few Monads More of the very nice tutorial "Learn You a Haskell for a Great Good" the author defines the following monad:

``````import Data.Ratio
newtype Prob a = Prob { getProb :: [(a,Rational)] } deriving Show
flatten :: Prob (Prob a) -> Prob a
flatten (Prob xs) = Prob \$ concat \$ map multAll xs
where multAll (Prob innerxs,p) = map (\(x,r) -> (x,p*r)) innerxs
instance Monad Prob where
return x = Prob [(x,1%1)]
m >>= f = flatten (fmap f m)
fail _ = Prob []
``````

I wondered if it is possible in Haskell to specialize the bind operator ">>=" in case the value in the monad belongs to a special typeclass like Eq, as I'd like to add up all probabilities belonging to the same value.

-

This is called a "restricted monad" and you define it like this:

``````{-# LANGUAGE ConstraintKinds, TypeFamilies, KindSignatures, FlexibleContexts, UndecidableInstances #-}
module Control.Restricted (RFunctor(..),
RApplicative(..),
import Prelude hiding (Functor(..), Monad(..))
import Data.Foldable (Foldable(foldMap))
import GHC.Exts (Constraint)

class RFunctor f where
type Restriction f a :: Constraint
fmap :: (Restriction f a, Restriction f b) => (a -> b) -> f a -> f b

class (RFunctor f) => RApplicative f where
pure :: (Restriction f a) => a -> f a
(<*>) :: (Restriction f a, Restriction f b) => f (a -> b) -> f a -> f b

class (RApplicative m) => RMonad m where
(>>=) :: (Restriction m a, Restriction m b) => m a -> (a -> m b) -> m b
(>>) :: (Restriction m a, Restriction m b)  => m a -> m b ->  m b
a >> b = a >>= \_ -> b
join :: (Restriction m a, Restriction m (m a)) => m (m a) -> m a
join a = a >>= id
fail :: (Restriction m a) => String -> m a
fail = error

return :: (RMonad m, Restriction m a) => a -> m a
return = pure

class (RMonad m) => RMonadPlus m where
mplus :: (Restriction m a) => m a -> m a -> m a
mzero :: (Restriction m a) => m a
msum :: (Restriction m a, Foldable t) => t (m a) -> m a
msum t = getRMonadPlusMonoid \$ foldMap RMonadPlusMonoid t

data RMonadPlusMonoid m a = RMonadPlusMonoid { getRMonadPlusMonoid :: m a }

instance (RMonadPlus m, Restriction m a) => Monoid (RMonadPlusMonoid m a) where
mappend (RMonadPlusMonoid x) (RMonadPlusMonoid y) = RMonadPlusMonoid \$ mplus x y
mempty = RMonadPlusMonoid mzero
mconcat t = RMonadPlusMonoid . msum \$ map getRMonadPlusMonoid t

guard :: (RMonadPlus m, Restriction m a) => Bool -> m ()
guard p = if p then return () else mzero
``````

To use a restricted monad, you need to begin your file like this:

``````{-# LANGUAGE ConstraintKinds, TypeFamilies, RebindableSyntax #-}
module {- module line -} where
import Prelude hiding (Functor(..), Monad(..))
import Control.Restricted
``````
-
Thanks for the quick answer. I'll have to think about it for a bit (before accepting). –  j.p. Mar 3 '13 at 21:21
Turns out someone at last put a "standard" implementation of constrained versions of the category classes on Hackage, though it doesn't seem complete yet (notably lacks `Monad`...) (the development version does have it already) –  leftaroundabout Mar 4 '13 at 0:54
I just managed to compile your code under ghc 7.4.2. For this I had to add "where" at end of the line starting with "instance", an "m" before the b at the end of the line starting with (>>), a line "import GHC.Prim (Constraint)" and add the language feature "UndecidableInstances". Next I try to use it... –  j.p. Mar 4 '13 at 10:55
@jug Thanks! I'll update the post. –  Ptharien's Flame Mar 5 '13 at 2:37

Thanks to Ptharien's Flame's answer (please upvote it!) I managed to adapt the example monad from "Learn You a Haskell for a Great Good" running. As I had to google some details (being a Haskell-newbie) here is what I did at the end (the example flipThree in "Learn..." gives now [(True,9 % 40), (False,31 % 40)]):

file Control/Restricted.hs (to shorten it I removed RApplicative, RMonadPlus etc):

``````{-# LANGUAGE ConstraintKinds, TypeFamilies, KindSignatures, FlexibleContexts, UndecidableInstances #-}
module Control.Restricted (RFunctor(..),
import Prelude hiding (Functor(..), Monad(..))
import Data.Foldable (Foldable(foldMap))
import Data.Monoid
import GHC.Exts (Constraint)

class RFunctor f where
type Restriction f a :: Constraint
fmap :: (Restriction f a, Restriction f b) => (a -> b) -> f a -> f b

class (RFunctor m) => RMonad m where
return :: (Restriction m a) => a -> m a
(>>=) :: (Restriction m a, Restriction m b) => m a -> (a -> m b) -> m b
(>>) :: (Restriction m a, Restriction m b)  => m a -> m b -> m b
a >> b = a >>= \_ -> b
join :: (Restriction m a, Restriction m (m a)) => m (m a) -> m a
join a = a >>= id
fail :: (Restriction m a) => String -> m a
fail = error
``````

file Prob.hs:

``````{-# LANGUAGE ConstraintKinds, TypeFamilies, RebindableSyntax, FlexibleContexts #-}
import Data.Ratio
import Control.Restricted
import Prelude hiding (Functor(..), Monad(..))
import Control.Arrow (first, second)
import Data.List (all)

newtype Prob a = Prob { getProb :: [(a, Rational)] } deriving Show

instance RFunctor Prob where
type Restriction Prob a = (Eq a)
fmap f (Prob as) = Prob \$ map (first f) as

flatten :: Prob (Prob a) -> Prob a
flatten (Prob xs) = Prob \$ concat \$ map multAll xs
where multAll (Prob innerxs, p) = map (\(x, r) -> (x, p*r)) innerxs

compress :: Eq a => Prob a -> Prob a
compress (Prob as) = Prob \$ foldr f [] as
where f a [] = [a]
f (a, p) ((b, q):bs) | a == b    = (a, p+q):bs
| otherwise = (b, q):f (a, p) bs

instance Eq a => Eq (Prob a) where
(==) (Prob as) (Prob bs) = all (`elem` bs) as

instance RMonad Prob where
return x = Prob [(x, 1%1)]
m >>= f = compress \$ flatten (fmap f m)
fail _ = Prob []
``````
-

Here another possibility based on Generalized Algebraic Datatypes using a technique by Ganesh Sittampalam:

``````{-# LANGUAGE GADTs #-}

import Control.Arrow (first, second)
import Data.Ratio
import Data.List (foldl')

-- monads over typeclass Eq
class EqMonad m where
eqReturn :: Eq a => a -> m a
eqBind :: (Eq a, Eq b) => m a -> (a -> m b) -> m b
eqFail :: Eq a => String -> m a
eqFail = error

data AsMonad m a where
Embed :: (EqMonad m, Eq a) => m a -> AsMonad m a
Return :: EqMonad m => a -> AsMonad m a
Bind :: EqMonad m => AsMonad m a -> (a -> AsMonad m b) -> AsMonad m b

return = Return
(>>=) = Bind
fail = error

unEmbed :: Eq a => AsMonad m a -> m a
unEmbed (Embed m) = m
unEmbed (Return v) = eqReturn v
unEmbed (Bind (Embed m) f) = m `eqBind` (unEmbed . f)
unEmbed (Bind (Return v) f) = unEmbed (f v)
unEmbed (Bind (Bind m f) g) = unEmbed (Bind m (\x -> Bind (f x) g))

-- the example monad from "Learn you a Haskell for a Great good"
newtype Prob a = Prob { getProb :: [(a, Rational)] }
deriving Show

instance Functor Prob where
fmap f (Prob as) = Prob \$ map (first f) as

flatten :: Prob (Prob a) -> Prob a
flatten (Prob xs) = Prob \$ concat \$ map multAll xs
where multAll (Prob innerxs, p) = map (\(x, r) -> (x, p*r)) innerxs

compress :: Eq a => Prob a -> Prob a
compress (Prob as) = Prob \$ foldl' f [] as
where f [] a = [a]
f ((b, q):bs) (a, p) | a == b    = (a, p+q):bs
| otherwise = (b, q):f bs (a, p)

instance Eq a => Eq (Prob a) where
(==) (Prob as) (Prob bs) = all (`elem` bs) as

instance EqMonad Prob where
eqReturn x = Prob [(x, 1%1)]
m `eqBind` f = compress \$ flatten (fmap f m)
eqFail _ = Prob []

newtype Probability a = Probability { getProbability :: AsMonad Prob a }

instance Monad Probability where
return = Probability . Return
a >>= f = Probability \$ Bind (getProbability a) (getProbability . f)
fail = error

instance (Show a, Eq a) => Show (Probability a) where
show = show . getProb . unEmbed . getProbability

-- Example flipping four coins (now as 0/1)
prob :: Eq a => [(a, Rational)] -> Probability a
prob = Probability . Embed . Prob

coin :: Probability Int
coin = prob [(0, 1%2), (1, 1%2)]

loadedCoin :: Probability Int
loadedCoin = prob [(0, 1%10), (1, 9%10)]

flipFour :: Probability Int
flipFour = do
a <- coin
b <- coin
c <- coin