In Haskell, sometimes for performance people will use unsafeCoerce (or the safer coerce) to translate between types that have the same internal representation. The most common example of this that I know of is for lists of newtypes:

newtype Identity a = Identity a

f :: [Identity a] -> [a]
f = coerce

Now, I have two GADTs in a codebase I'm working on that look something like this pared down:

data Typ where
    PredT :: Typ
    ProcT :: [Typ] -> Typ
    IntT :: Typ
    ListT :: Typ -> Typ

data HKTyp v (f :: * -> * -> *) where
    HKPredT :: HKTyp v f
    HKProcT :: [HKTyp v f] -> HKTyp v f
    HKIntT :: HKTyp v f
    HKListT :: f v (HKTyp v f) -> HKTyp v f  

I need these types to be different (rather than using the later as a generalization of the former), because the singletons library (or at least the template haskell functions) doesn't like higher-kinded data. Now, because I have to keep these types separate, I want to have some conversion functions between them:

newtype Id v a = Id a

promoteHK :: Typ -> HKTyp v Id
promoteHK PredT = HKPredT
promoteHK (ProcT ts) = HKProcT (fmap promoteHK ts)
promoteHK IntT = HKIntT
promoteHK (ListT x) = HKListT (Id $ promoteHK x)

demoteHK :: HKTyp v Id -> Typ
demoteHK HKPredT = PredT
demoteHK (HKProcT (Id ts)) = ProcT (fmap demoteHK ts)
demoteHK HKIntT = IntT
demoteHK (HKListT (Id x)) = HKListT x

These are pretty mechanical to write, but that's not the issue.

While I'm sure in many cases, GHC could inline and beta-reduce applications of demoteHK and promoteHK at compile time, thus not causing any runtime costs for doing these conversions, I really want to be able to write

f :: [Typ] -> [HKTyp v Id]
f = coerce

to avoid traversing the data structure, since these types are so similar, and hence (I assume) should have the same underlying representation in memory.

My question is two-fold.

  1. Do these types in fact have the same memory representation in GHC?
  2. Are there strong guarantees in GHC for how (G)ADTs are laid out in memory that lets you do things like this in general?
  • @chi Yes, good catch. I have corrected this. Feb 2, 2021 at 14:31
  • 1
    I'd be tempted to try unsafeCoerce between these two types and see if I can cause a crash. If I can, well, they have different runtime representation. Otherwise, no definitive conclusion can be reached. Not much, but better than nothing. I suspect that current GHC uses the same representation and the coercion is safe, but that the GHC devs do not want to guarantee that will always be the case forever (?)
    – chi
    Feb 2, 2021 at 14:33
  • @chi Looking at the documentation for #unsafeCoerce, that does seem to be the case. If this use-case was guaranteed by the GHC devs, I'd imagine it would be documented there. This seems like it's something that's pretty unlikely to change in the future (i.e. tagged unions use tags internally by order of constructors listed), so it might be worth making a GHC proposal for having this case included in the Data.Coerce system, so that unsafeCoerce doesn't have to be used. Feb 2, 2021 at 14:40
  • To answer my question 1, testing this out on GHCI, these types do seem to have the same representation. Feb 2, 2021 at 14:40
  • 1
    Perhaps your codebase versions are GADTs, but the data decls you show use GADT syntax but are not GADTs. That is, the constructor sigs all end ... -> Typ resp ... -> HKTyp v f (and there's no constraints).
    – AntC
    Feb 2, 2021 at 20:56

1 Answer 1


I haven't tested the performance of the following, and it may be convoluted enough that GHC, in fact, can't optimize it, but it will let us build a better tool. The idea is to use Generics.

The plan is to define a type class that coerces two types that have the same Generic structure along with a function that makes use of the class. Consider the following:

{-# LANGUAGE DeriveGeneric #-}
import GHC.Generics

class GenericCoerce a b where
  genericCoerce' :: a x -> b x

genericCoerce :: (Generic x, Generic y, GenericCoerce (Rep x) (Rep y)) => x -> y
genericCoerce = to . genericCoerce' . from

Of course, we still need to define what makes two Reps coercible, but just like your promoteHK and demoteHK definitions, this is somewhat mechanical:

{-# LANGUAGE LambdaCase #-}
{-# LANGUAGE EmptyCase #-}

instance GenericCoerce V1 V1 where
  genericCoerce' = \case

instance GenericCoerce U1 U1 where
  genericCoerce' = id

instance (GenericCoerce f f', GenericCoerce g g') => GenericCoerce (f :+: g) (f' :+: g') where
  genericCoerce' (L1 x) = L1 (genericCoerce' x)
  genericCoerce' (R1 x) = R1 (genericCoerce' x)

instance (GenericCoerce f f', GenericCoerce g g') => GenericCoerce (f :*: g) (f' :*: g') where
  genericCoerce' (x :*: y) = genericCoerce' x :*: genericCoerce' y

instance GenericCoerce cs1 cs2 => GenericCoerce (M1 t m cs1) (M1 t m' cs2) where
  genericCoerce' (M1 x) = M1 (genericCoerce' x)

instance (Generic x, Generic y, GenericCoerce (Rep x) (Rep y)) => GenericCoerce (K1 t x) (K1 t y) where
  genericCoerce' (K1 x) = K1 (genericCoerce x)

This actually works for very basic cases! Consider a data type like:

data Foo = Bar | Baz
  deriving (Generic, Show)

We get the behavior we want:

> genericCoerce @Bool @Foo True

> genericCoerce @Foo @Bool Bar

However, the problem with this Generic way of doing coercion is that it doesn't exactly play nicely with the normal way of coercing data types. Specifically, the type rep of a given type and the type rep of that type wrapped in a newtype wrapper are not the same.

One possible solution is the use of (gasp) incoherent instances. This may be a line too far for you, but if you're okay with them, consider the following two additional instances:

-- instances to handle newtype constructor
instance {-# INCOHERENT #-} (Generic x, Rep x ~ D1 m x', GenericCoerce x' y) => GenericCoerce (C1 m2 (S1 m3 (Rec0 x))) y where
  genericCoerce' = genericCoerce' . unM1 . from . unK1 . unM1 . unM1

instance {-# INCOHERENT #-} (Generic y, Rep y ~ D1 m y', GenericCoerce x y') => GenericCoerce x (C1 m2 (S1 m3 (Rec0 y))) where
  genericCoerce' = M1 . M1 . K1 . to . M1 . genericCoerce'

These two instances specifically target the case where one of the types has a newtype wrapper. Incoherent instances are considered dangerous, and if you have a lot of nested types/newtypes in your coercion, perhaps something could go wrong. That said, with these two instance in play, you're good to go with the example you gave:

promoteHK :: Typ -> HKTyp v Id
promoteHK = genericCoerce

demoteHK :: HKTyp v Id -> Typ
demoteHK = genericCoerce

In action:

> promoteHK PredT

> promoteHK (ListT PredT)
HKListT (Id HKPredT)

> promoteHK (ListT (ListT (ListT PredT)))
HKListT (Id (HKListT (Id (HKListT (Id HKPredT)))))

> demoteHK (HKProcT [HKIntT, HKPredT])
ProcT [IntT,PredT]

So far, I haven't quite answered your question. You asked if two seemingly isomorphic types really do have the same memory representation in GHC and if there are any guarantees in GHC that let you do things like this in general (I assume by "things like this", you mean coercions between isomorphic data types).

As far as I'm aware, there are no guarantees from GHC, but genericCoerce has given us a slightly firmer ground to walk on. Excluding the incoherent instances hack, the original version of genericCoerce converts a data type with phantom type parameters into the same datatype just with different phantom parameters. Technically, I can provide no guarantee that GHC will store multiple instances of the same runtime data the same way, but it seems to me like a pretty easy assumption to make.

Once we add in the incoherent instances and the newtype wrapper shenanigans, we're standing on less solid grounds, but the fact that it all works is some consolation.

Indeed, now that we see that the core of genericCoerce really is a coercion (we're building the same data type up from what was just destructed in every case), and if we trust that the newtype-wrapper incoherent instances also function as a coercion, then we can write:

genericCoerceProbablySafe :: (Generic x, Generic y, GenericCoerce (Rep x) (Rep y)) => x -> y
genericCoerceProbablySafe = unsafeCoerce

We get better performance than genericCoerce and more type safety than unsafeCoerce, and we've reduced your questions down to: "Is the Generic Rep an accurate proxy for how GHC stores memory (up to newtype wrappers)?"

  • You say this addresses the "criteria of concise definitions". But the OP never listed that as a criterion! The only criteria listed are performance and correctness. The correct variant at the beginning is certainly going to be no better than the hand-written conversion in terms of performance (and almost certainly worse, given all the indirection involved). And sure, your unsafeCoerce implementation at the end will have good performance, but you just assume it's correct outright, and OP explicitly asked whether that assumption was right. Feb 4, 2021 at 18:06
  • I misread. The OP say "I really want to be able to write f = coerce" after showing a long definition, and I didn't realize the next few lines were a continuation of that sentence. As for unsafeCoerce, I make two explicit assumptions: 1) The GenericCoerce constraint will limit the function to only being called on types that have the same Generic structure, and 2) the Generic rep mimics the memory rep. Thus, I'm reducing OP's question from "do we have any guarantees about memory of GADTs" to "Can we assume that the Generic rep mimics memory?" I thought that was an improvement.
    – DDub
    Feb 4, 2021 at 19:12
  • @DanielWagner I've updated the answer to try to be clearer about the conclusion. It doesn't definitively answer the OP's questions, but it does provide alternate ways to think about them. Thanks for pushing me toward clarity and improvement.
    – DDub
    Feb 4, 2021 at 19:51

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