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In Haskell, you can use unsafeCoerce to override the type system. How to do the same in F#?

For example, to implement the Y-combinator.

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:?> maybe - could you provide a more concrete example of what you want. Otherwise box |> unbox might work –  John Palmer Dec 29 '13 at 8:10
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for update - see here stackoverflow.com/questions/1998407/… –  John Palmer Dec 29 '13 at 8:18

2 Answers 2

up vote 5 down vote accepted

I'd like to offer a different solution, based on embedding the untyped lambda calculus in a typed functional language. The idea is to create a data type that allows us to change between types α and α → α, which subsequently allows to escape the restrictions of a type system. I'm not very familiar with F# so I'll give my answer in Haskell, but I believe it could be adapted easily (perhaps the only complication could be F#'s strictness).

-- | Roughly represents morphism between @a@ and @a -> a@.
-- Therefore we can embed a arbitrary closed λ-term into @Any a@. Any time we
-- need to create a λ-abstraction, we just nest into one @Any@ constructor.
--
-- The type parameter allows us to embed ordinary values into the type and
-- retrieve results of computations.
data Any a = Any (Any a -> a)

Note that the type parameter isn't significant for combining terms. It just allows us to embed values into our representation and extract them later. All terms of a particular type Any a can be combined freely without restrictions.

-- | Embed a value into a λ-term. If viewed as a function, it ignores its
-- input and produces the value.
embed :: a -> Any a
embed = Any . const

-- | Extract a value from a λ-term, assuming it's a valid value (otherwise it'd
-- loop forever).
extract :: Any a -> a
extract x@(Any x') = x' x

With this data type we can use it to represent arbitrary untyped lambda terms. If we want to interpret a value of Any a as a function, we just unwrap its constructor.

First let's define function application:

-- | Applies a term to another term.
($$) :: Any a -> Any a -> Any a
(Any x) $$ y = embed $ x y

And λ abstraction:

-- | Represents a lambda abstraction
l :: (Any a -> Any a) -> Any a
l x = Any $ extract . x

Now we have everything we need for creating complex λ terms. Our definitions mimic the classical λ-term syntax, all we do is using l to construct λ abstractions.

Let's define the Y combinator:

-- λf.(λx.f(xx))(λx.f(xx))
y :: Any a
y = l (\f -> let t = l (\x -> f $$ (x $$ x))
              in t $$ t)

And we can use it to implement Haskell's classical fix. First we'll need to be able to embed a function of a -> a into Any a:

embed2 :: (a -> a) -> Any a
embed2 f = Any (f . extract)

Now it's straightforward to define

fix :: (a -> a) -> a
fix f = extract (y $$ embed2 f)

and subsequently a recursively defined function:

fact :: Int -> Int
fact = fix f
  where
    f _ 0 = 1
    f r n = n * r (n - 1)

Note that in the above text there is no recursive function. The only recursion is in the Any data type, which allows us to define y (which is also defined non-recursively).

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In Haskell, unsafeCoerce has the type a -> b and is generally used to assert to the compiler that the thing being coerced actually has the destination type and it's just that the type-checker doesn't know it.

Another, less common use, is to reinterpret a pattern of bits as another type. For example an unboxed Double# could be reinterpreted as an unboxed Int64#. You have to be sure about the underlying representations for this to be safe.

In F#, the first application can be achieved with box |> unbox as John Palmer said in a comment on the question. If possible use explicit type arguments to make sure that you don't accidentally have the wrong coercion inferred, e.g. box<'a> |> unbox<'b> where 'a and 'b are type variables or concrete types that are already in scope in your code.

For the second application, look at the BitConverter class for specific conversions of bit-patterns. In theory you could also do something like interfacing with unmanaged code to achieve this, but that seems very heavyweight.

These techniques won't work for implementing the Y combinator because the cast is only valid if the runtime objects actually do have the target type, but with the Y combinator you actually need to call the same function again but with a different type. For this you need the kinds of encoding tricks mentioned in the question John Palmer linked to.

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