You can think of typeclass constraints essentially as implicit parameters -- i.e. think of

```
Foo a => b
```

as

```
FooDict a -> b
```

where `FooDict a`

is a dictionary of methods defined in the class `Foo`

. For example, `EqDict`

would be the following record:

```
data EqDict a = EqDict { equal :: a -> a -> Bool, notEqual :: a -> a -> Bool }
```

The differences are that there can only be one value of each dictionary at each type (generalize appropriately for MPTCs), and GHC fills in its value for you.

With this in mind, we can come back to your signatures.

```
type FooT m a = (MyMonad m) => ListT m a
foo :: MyType a -> MyOtherType a -> FooT m a
```

expands to

```
foo :: MyType a -> MyOtherType a -> (MyMonad m => ListT m a)
```

using the dictionary interpretation

```
foo :: MyType a -> MyOtherType a -> MyMonadDict m -> ListT m a
```

which is equivalent by reordering of arguments to

```
foo :: MyMonadDict m -> MyType a -> MyOtherType a -> ListT m a
```

which is equivalent by the inverse of the dictionary transformation to

```
foo :: (MyMonad m) => MyType a -> MyOtherType a -> ListT m a
```

which is what you were looking for.

However, things do not work out that way in your other example.

```
type Bar a b = (Something a, SomethingElse b) => NotAsBar a b
bar :: Bar a b -> InsertTypeHere
```

expands to

```
bar :: ((Something a, SomethingElse b) => NotAsBar a b) -> InsertTypeHere
```

These variables are still quantified at the top level (i.e.

```
bar :: forall a b. ((Something a, SomethingElse b) => NotAsBar a b) -> InsertTypeHere
```

), since you mentioned them explicitly in `bar`

's signature, but when we do the dictionary transformation

```
bar :: (SomethingDict a -> SomethingElseDict b -> NotAsBar a b) -> InsertTypeHere
```

we can see that this is not equivalent to

```
bar :: SomethingDict a -> SomethingElseDict b -> NotAsBar a b -> InsertTypeHere
```

which would give rise to what you want.

It's pretty tough to come up with realistic examples in which a typeclass constraint is used at a different place than its point of quantification -- I have never seen it in practice -- so here's an unrealistic one just to show that that's what's happening:

```
sillyEq :: forall a. ((Eq a => Bool) -> Bool) -> a -> a -> Bool
sillyEq f x y = f (x == y)
```

Contrast to what happens if we use try to use `==`

when we are not passing an argument to `f`

:

```
sillyEq' :: forall a. ((Eq a => Bool) -> Bool) -> a -> a -> Bool
sillyEq' f x y = f (x == y) || x == y
```

we get a *No instance for *`Eq a`

error.

The `(x == y)`

in `sillyEq`

gets its `Eq`

dict from `f`

; its dictionary form is:

```
sillyEq :: forall a. ((EqDict a -> Bool) -> Bool) -> a -> a -> Bool
sillyEq f x y = f (\eqdict -> equal eqdict x y)
```

Stepping back a bit, I think the way you are tersifying here is going to be painful -- I think you're wanting the mere use of something to quantify its context, where its context is defined as the "function signature where it is used". That notion has no simple semantics. You should be able to think of `Bar`

as function on sets: it takes as arguments two sets and returns another. I don't believe there will be such a function for the use you are trying to achieve.

As far as shortening contexts, you may be able to make use of the `ConstraintKinds`

extension which allows you to make constraint synonyms, so at least you could say:

```
type Bars a = (Something a, SomethingElse a)
```

to get

```
bar :: Bars a => Bar a b -> InsertTypeHere
```

But what you want still may be possible -- your names are not descriptive enough for me to tell. You may want to look into Existential Quantification and Universal Quantification, which are two ways of abstracting over type variables.

Moral of the story: remember that `=>`

is just like `->`

except that those arguments are filled in automatically by the compiler, and make sure that you are trying to define types with well-defined mathematical meanings.

`ListT m`

is a monad only if`m`

is commutative. See the docs and Haskell wiki. – Petr Pudlák Jan 29 '13 at 15:06