I'm not sure what you're driving at with that `test`

function, but you can do something like this if you like:

```
{-# LANGUAGE ScopedTypeVariables #-}
class NamedType a where
name :: a -> String
instance NamedType Int where
name _ = "Int"
instance NamedType Integer where
name _ = "Integer"
instance NamedType q => NamedType (Zq q) where
name _ = "Zq (" ++ name (undefined :: q) ++ ")"
```

I would not be doing my Stack Overflow duty if I did not follow up this answer with a warning: what you are asking for is very, very strange. You are probably doing something in a very unidiomatic way, and will be fighting the language the whole way. I strongly recommend that your next question be a much broader design question, so that we can help guide you to a more idiomatic solution.

**Edit**

There is another half to your question, namely, how to write a `test`

function that "pattern matches" on the input to check whether it's an `Int`

, an `Integer`

, a `Zq`

type, etc. You provide this suggestive code snippet:

```
test :: (Num a) => a -> a
test (Integer x) = x+2
test (Int x) = x+1
test (Zq x) = x
```

There are a couple of things to clear up here.

Haskell has three levels of objects: the value level, the type level, and the kind level. Some examples of things at the value level include `"Hello, world!"`

, `42`

, the function `\a -> a`

, or `fix (\xs -> 0:1:zipWith (+) xs (tail xs))`

. Some examples of things at the type level include `Bool`

, `Int`

, `Maybe`

, `Maybe Int`

, and `Monad m => m ()`

. Some examples of things at the kind level include `*`

and `(* -> *) -> *`

.

The levels are in order; value level objects are classified by type level objects, and type level objects are classified by kind level objects. We write the classification relationship using `::`

, so for example, `32 :: Int`

or `"Hello, world!" :: [Char]`

. (The kind level isn't too interesting for this discussion, but `*`

classifies types, and arrow kinds classify type constructors. For example, `Int :: *`

and `[Int] :: *`

, but `[] :: * -> *`

.)

Now, one of the most basic properties of Haskell is that each level is completely isolated. You will never see a string like `"Hello, world!"`

in a type; similarly, value-level objects don't pass around or operate on types. Moreover, there are separate *namespaces* for values and types. Take the example of `Maybe`

:

```
data Maybe a = Nothing | Just a
```

This declaration creates a new name `Maybe :: * -> *`

at the type level, and two new names `Nothing :: Maybe a`

and `Just :: a -> Maybe a`

at the value level. One common pattern is to use the same name for a type constructor and for its value constructor, if there's only one; for example, you might see

```
newtype Wrapped a = Wrapped a
```

which declares a new name `Wrapped :: * -> *`

at the type level, and simultaneously declares a distinct name `Wrapped :: a -> Wrapped a`

at the value level. Some particularly common (and confusing examples) include `()`

, which is both a value-level object (of type `()`

) and a type-level object (of kind `*`

), and `[]`

, which is both a value-level object (of type `[a]`

) and a type-level object (of kind `* -> *`

). Note that the fact that the value-level and type-level objects happen to be spelled the same in your source is just a coincidence! If you wanted to confuse your readers, you could perfectly well write

```
newtype Huey a = Louie a
newtype Louie a = Dewey a
newtype Dewey a = Huey a
```

where none of these three declarations are related to each other at all!

Now, we can finally tackle what goes wrong with `test`

above: `Integer`

and `Int`

are not value constructors, so they can't be used in patterns. Remember -- the value level and type level are isolated, so you can't put type names in value definitions! By now, you might wish you had written `test'`

instead:

```
test' :: Num a => a -> a
test' (x :: Integer) = x + 2
test' (x :: Int) = x + 1
test' (Zq x :: Zq a) = x
```

...but alas, it doesn't quite work like that. Value-level things aren't allowed to depend on type-level things. What you *can* do is to write *separate* functions at each of the `Int`

, `Integer`

, and `Zq a`

types:

```
testInteger :: Integer -> Integer
testInteger x = x + 2
testInt :: Int -> Int
testInt x = x + 1
testZq :: Num a => Zq a -> Zq a
testZq (Zq x) = Zq x
```

Then we can call the appropriate one of these functions when we want to do a test. Since we're in a statically-typed language, exactly one of these functions is going to be applicable to any particular variable.

Now, it's a bit onerous to remember to call the right function, so Haskell offers a slight convenience: you can let the compiler choose one of these functions for you at compile time. This mechanism is the big idea behind classes. It looks like this:

```
class Testable a where test :: a -> a
instance Testable Integer where test = testInteger
instance Testable Int where test = testInt
instance Num a => Testable (Zq a) where test = testZq
```

Now, it *looks* like there's a single function called `test`

which can handle any of `Int`

, `Integer`

, or numeric `Zq`

's -- but in fact there are three functions, and the compiler is transparently choosing one for you. And that's an important insight. The type of `test`

:

```
test :: Testable a => a -> a
```

...looks at first blush like it is a function that takes a value that could be any `Testable`

type. But in fact, it's a function that can be specialized to any `Testable`

type -- and then *only* takes values of that type! This difference explains yet another reason the original `test`

function didn't work. You can't have multiple patterns with variables at different types, because the function only ever works on a single type at a time.

The ideas behind the classes `NamedType`

and `Testable`

above can be generalized a bit; if you do, you get the `Typeable`

class suggested by hammar above.

I think now I've rambled more than enough, and likely confused more things than I've clarified, but leave me a comment saying which parts were unclear, and I'll do my best.