Assume that we have imported Data.Typeable which contains cast :: (Typeable a, Typeable b) -> a -> Maybe b.

Consider that

> cast 'n' :: Maybe Char
Just 'n'


> cast 7 :: Maybe Char

I understand the above, but it seems to be a trivial example. It doesn't reveal why someone would need to use the cast operator (as far as I can see).

Question: Is there an example of a usage of cast which genuinely "changes" the type of a value from one type to another? The closest example I can think of (which doesn't actually work in GHCi) would be changing the type of 7 from Integer to Double:

> cast 7 :: Maybe Double
Just '7' -- this doesn't work, as 7 is typed as a Integer above; instead GHCi returns Nothing
  • You're probably interested in this blog post. It predates Data.Coerce.coerce, so some of the things might get done differently today.
    – Zeta
    May 15, 2017 at 10:02

3 Answers 3


Is there an example of a usage of cast which genuinely "changes" the type of a value from one type to another?

The simple answer is no. But, there may be a situation in which you do not know your type, since it is "hidden" by the quantifier "exists". Here's an example:

{-# LANGUAGE ExistentialQuantification #-}

import Data.Typeable
import Data.Maybe

data Foo = forall a . Typeable a => Foo a

main = print . catMaybes . map (\(Foo x) -> cast x :: Maybe Bool) $ xs
    xs = [Foo True, Foo 'a', Foo "str", Foo False]

The output will be:


The purpose of the Typeable class is to allow you to work with data when you don't know its exact type. The purpose of the cast operator is to check whether some data has a specific type, and if so, let you work with it as that type. It's all about doing stuff to the type signature of your data. The actual value does not change at all.

If you want to change the value of some data, that's not a cast, that's a conversion. All sorts of functions out there to do that. E.g., fromIntegral turns something that's an instance of Integral into something else. (E.g., Int to Double.) That's not what casting is about though.


Suppose you want to implement a function which acts as the identity function on all values, except for integers where it should act as the successor function.

In an untyped language like Python, this is simple:

>>> def f(x):
...   if type(x) == int:
...     return x+1
...   else:
...     return x
>>> f(42)
>>> f("qwerty")

Even in Java, this is doable, even if it requires some casting:

static <A> A f(A a) {
    if (a instanceof Integer)
        return (A) (Integer) ((Integer) a + 1);
        return a;

public static void main (String[] args) throws java.lang.Exception
    System.out.println(">> " + f(42));
    System.out.println(">> " + f("qwerty"));

/*  Output:
>> 43
>> qwerty

What about Haskell?

In Haskell, this can not be done. Any function of type forall a. a -> a must either fail to terminate, or behave as the identity. This is a direct consequence of the free theorem associated to that type.

However, if we can add a Typeable constraint on type a, then it becomes possible:

f :: forall a. Typeable a => a -> a
f x = case cast x :: Maybe Int of
   Nothing -> x
   Just n  -> case cast (n+1) :: Maybe a of
      Nothing -> x
      Just y -> y

The first cast converts a to Int, the second cast converts a back to Int.

The code above is quite ugly, since we know that the second cast cannot fail, so there's no real need for the second cast. We can improve the code above with eqT and a type-equality GADT:

f :: forall a. Typeable a => a -> a
f x = case eqT :: Maybe (a :~: Int) of
   Nothing   -> x
   Just Refl -> x+1

Basically, eqT tells us whether two (Typeable) types are equal. Even better, after matching with Just Refl, the compiler also knows that they are equal, and allows us to use Int vales instead of a values, interchangeably, and with no casts.

Indeed, thanks to GADTs, :~: and eqT, now most uses of cast are now obsolete. cast itself can be trivially implemented with eqT:

cast :: forall a. (Typeable a, Typeable b) => a -> Maybe b
cast x = case eqT :: Maybe (a :~: b) of
   Nothing   -> Nothing
   Just Refl -> Just x

Conclusion: in Haskell, we get the best of both world. We do have parametricity guarantees (free theorems) for polymorphic types. We can also break those parametricity guarantees, and use "ad hoc" polymorphism, at the price of an additional Typeable constraint.

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