**[a follow-up to Gabriel Gonzalez answer]**

The right notation for constraints and quantifications in Haskell is the following:

```
<functions-definition> ::= <functions> :: <quantified-type-expression>
<quantified-type-expression> ::= forall <type-variables-with-kinds> . (<constraints>) => <type-expression>
<type-expression> ::= <type-expression> -> <quantified-type-expression>
| ...
...
```

Kinds can be omitted, as well as `forall`

s for rank-1 types:

```
<simply-quantified-type-expression> ::= (<constraints-that-uses-rank-1-type-variables>) => <type-expression>
```

For example:

```
{-# LANGUAGE Rank2Types #-}
msum :: forall m a. Monoid (m a) => [m a] -> m a
msum = mconcat
mfilter :: forall m a. (Monad m, Monoid (m a)) => (a -> Bool) -> m a -> m a
mfilter p ma = do { a <- ma; if p a then return a else mempty }
guard :: forall m. (Monad m, Monoid (m ())) => Bool -> m ()
guard True = return ()
guard False = mempty
```

or without `Rank2Types`

(since we only have rank-1 types here), and using `CPP`

(j4f):

```
{-# LANGUAGE CPP #-}
#define MonadPlus(m, a) (Monad m, Monoid (m a))
msum :: MonadPlus(m, a) => [m a] -> m a
msum = mconcat
mfilter :: MonadPlus(m, a) => (a -> Bool) -> m a -> m a
mfilter p ma = do { a <- ma; if p a then return a else mempty }
guard :: MonadPlus(m, ()) => Bool -> m ()
guard True = return ()
guard False = mempty
```

The "problem" is that we can't write

```
class (Monad m, Monoid (m a)) => MonadPlus m where
...
```

or

```
class forall m a. (Monad m, Monoid (m a)) => MonadPlus m where
...
```

**That is, **`forall m a. (Monad m, Monoid (m a))`

can be used as a standalone constraint, but can't be aliased with a new one-parametric typeclass for `*->*`

types.

This is because the typeclass defintion mechanism works like this:

```
class (constraints[a, b, c, d, e, ...]) => ClassName (a b c) (d e) ...
```

i.e. the **rhs** side introduce type variables, not the lhs or `forall`

at the lhs.

Instead, we need to write 2-parametric typeclass:

```
{-# LANGUAGE MultiParamTypeClasses, FlexibleContexts, FlexibleInstances #-}
class (Monad m, Monoid (m a)) => MonadPlus m a where
mzero :: m a
mzero = mempty
mplus :: m a -> m a -> m a
mplus = mappend
instance MonadPlus [] a
instance Monoid a => MonadPlus Maybe a
msum :: MonadPlus m a => [m a] -> m a
msum = mconcat
mfilter :: MonadPlus m a => (a -> Bool) -> m a -> m a
mfilter p ma = do { a <- ma; if p a then return a else mzero }
guard :: MonadPlus m () => Bool -> m ()
guard True = return ()
guard False = mzero
```

Cons: we need to specify second parameter every time we use `MonadPlus`

.

Question: how

```
instance Monoid a => MonadPlus Maybe a
```

can be written if `MonadPlus`

is one-parametric typeclass? `MonadPlus Maybe`

from `base`

:

```
instance MonadPlus Maybe where
mzero = Nothing
Nothing `mplus` ys = ys
xs `mplus` _ys = xs
```

works not like `Monoid Maybe`

:

```
instance Monoid a => Monoid (Maybe a) where
mempty = Nothing
Nothing `mappend` m = m
m `mappend` Nothing = m
Just m1 `mappend` Just m2 = Just (m1 `mappend` m2) -- < here
```

:

```
(Just [1,2] `mplus` Just [3,4]) `mplus` Just [5,6] => Just [1,2]
(Just [1,2] `mappend` Just [3,4]) `mappend` Just [5,6] => Just [1,2,3,4,5,6]
```

Analogically, `forall m a b n c d e. (Foo (m a b), Bar (n c d) e)`

gives rise for (7 - 2 * 2)-parametric typeclass if we want `*`

types, (7 - 2 * 1)-parametric typeclass for `* -> *`

types, and (7 - 2 * 0) for `* -> * -> *`

types.

is, what its weaknesses are, and whether there are existing plans to improve on it. – Dan Burton Oct 9 '12 at 18:56