I'm writing a type class for my `pipes`

library to define an abstract interface to `Proxy`

-like types. The type class looks something like:

```
class ProxyC p where
idT :: (Monad m) => b' -> p a' a b' b m r
(<-<) :: (Monad m)
=> (c' -> p b' b c' c m r)
-> (b' -> p a' a b' b m r)
-> (c' -> p a' a c' c m r)
... -- other methods
```

I'm also writing extensions for the `Proxy`

type that are of the form:

```
instance (ProxyC p) => ProxyC (SomeExtension p) where ....
```

... and I'd like these instances to be able to impose an additional constraint that if `m`

is a `Monad`

then `p a' a b' b m`

is a `Monad`

for all `a'`

, `a`

, `b'`

, and `b`

.

However, I have no clue how to cleanly encode that as a constraint either for the `ProxyC`

class or for the instances. The only solution I currently know of is to do something like encoding it in the method signatures of the class:

```
(<-<) :: (Monad m, Monad (p b' b c' c m), Monad (p a' a b' b m))
=> (c' -> p b' b c' c m r)
-> (b' -> p a' a b' b m r)
-> (c' -> p a' a c' c m r)
```

... but I was hoping there would be a simpler and more elegant solution.

**Edit**: And not even that last solution works, since the compiler does not deduce that `(Monad (SomeExtension p a' a b' b m))`

implies `(Monad (p a' a b' b m))`

for a specific choice of variables, even when given the following instance:

```
instance (Monad (p a b m)) => Monad (SomeExtension p a b m) where ...
```

**Edit #2**: The next solution I'm considering is just duplicating the methods for the `Monad`

class within the `ProxyC`

class:

```
class ProxyC p where
return' :: (Monad m) => r -> p a' a b' b m r
(!>=) :: (Monad m) => ...
```

... and then instantiating them with each `ProxyC`

instance. This seems okay for my purposes since the `Monad`

methods only need to be used internally for extension writing and the original type still has a proper `Monad`

instance for the downstream user. All this does is just expose the `Monad`

methods to the instance writer.