The existing `Monad`

typeclass expects your type to work for *every* possible type argument. Consider `Maybe`

: in `Maybe a`

, `a`

is not constrained at all. Basically **you can't have a Monad with constraints**.

This is a fundamental limitation of how the `Monad`

class is defined—I don't know of any way to get around it without modifying that.

This is also a problem for defining `Monad`

instances for other common types, like `Set`

.

In practice, this restriction is actually pretty important. Consider that (normally) functions are *not* instances of `Num`

. This means that we could not use your monad to contain a function! This really limits important operations like `ap`

(`<*>`

from `Applicative`

), since that depends on a monad containing a function:

```
ap :: Monad m => m (a -> b) -> m a -> m b
```

Your monad would not support many common uses and idioms we've grown to expect from normal monads! This would rather limit its utility.

Also, as a side-note, you should generally avoid using `fail`

. It doesn't really fit in with the `Monad`

typeclass: it's more of a historic accident. Most people agree that you should avoid it in general: it was just a hack to deal with failed pattern matches in do-notation.

That said, looking at how to define a restricted monad class is a great exercise for understanding a few Haskell extensions and learning some intermediate/advanced Haskell.

## Alternatives

With the downsides in mind, here are a couple of alternatives—replacements for the standard `Monad`

class that *do* support restricted monads.

### Constraint Kinds

I can think of a couple of possible alternatives. The most modern one would be taking advantage of the `ConstraintKind`

extension in GHC, which lets you reify typeclass constraints as kinds. This blog post details how to implement a restricted monad using constraint kinds; once I've read it, I'll summarize it here.

The basic idea is simple: with `ConstraintKind`

, we can turn our constrain (`Num a`

) into a type. We can then have a new `Monad`

class which contains this type as a member (just like `return`

and `fail`

are members) and allows use to overload the constraint with `Num a`

. This is what the code looks like:

```
{-# LANGUAGE ConstraintKinds #-}
{-# LANGUAGE TypeFamilies #-}
module Main where
import Prelude hiding (Monad (..))
import GHC.Exts
class Monad m where
type Restriction m a :: Constraint
type Restriction m a = ()
return :: Restriction m a => a -> m a
(>>=) :: Restriction m a => m a -> (a -> m b) -> m b
fail :: Restriction m a => String -> m a
data IDnum a = IDnum a
instance Monad IDnum where
type Restriction IDnum a = Num a
return = IDnum
IDnum x >>= f = f x
fail _ = return 0
```

### RMonad

There is an existing library on hackage called rmonad (for "restricted monad") which provides a more general typeclass. You could probably use this to write your desired monad instance. (I haven't used it myself, so it's a bit hard to say.)

It doesn't use the `ConstraintKinds`

extension and (I believe) supports older versions of GHC. However, I think it's a bit ugly; I'm not sure that it's the best option any more.

Here's the code I came up with:

```
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE TypeFamilies #-}
import Prelude hiding (Monad (..))
import Control.RMonad
import Data.Suitable
data IDnum a = IDnum a
data instance Constraints IDnum a = Num a => IDnumConstraints
instance Num a => Suitable IDnum a where
constraints = IDnumConstraints
instance RMonad IDnum where
return = IDnum
IDnum x >>= f = f x
fail _ = withResConstraints $ \ IDnumConstraints -> return 0
```

## Further Reading

For more details, take a look at this SO question.

Oleg has an article about this pertaining specifically to the Set monad, which might be interesting: "How to restrict a monad without breaking it".

Finally, there are a couple of papers you could also read:

`Set`

(and other containers with constraints) using the continuation monad – Petr Pudlák Mar 11 '14 at 6:27