I'm working with data types of this shape, using V from linear:

type Foo n = V (n * 3) Double -> Double

Having it fixed on n is pretty important, because I want to be able to ensure that I'm passing in the right number of elements at compile-time. This is a part of my program that already works well, independent of what I'm doing here.

For any KnownNat n, I can generate a Foo n satisfying the behavior that my program needs. For the purposes of this question it can be something silly like

mkFoo :: KnownNat (n * 3) => Foo n
mkFoo = sum

Or for a more meaningful example, it can generate a random V of the same length and use dot on the two. The KnownNat constraint here is redundant, but in reality, it's needed to do make a Foo. I make one Foo and use it for my entire program (or with multiple inputs), so this guarantees me that whenever I use it, I'm using on things with the same length, and on things that the structure of the Foo dictates.

And finally, I have a function that makes inputs for a Foo:

bar :: KnownNat (n * 3) => Proxy n -> [V (n * 3) Double]

bar is actually the reason why i'm using n * 3 as a type function, instead of just manually expanding it out. The reason is that bar might do its job by using three vectors of length n and appending them all together as a vector of length n * 3. Also, n is a much more meaningful parameter to the function, semantically, than n * 3. This also lets me disallow improper values like n's that aren't multiples of 3, etc.

Now, before, everything worked fine as long as I defined a type synonym at the beginning:

type N = 5

And I can just then pass in Proxy :: Proxy N to bar, and use mkFoo :: Foo N. And everything worked fine.

-- works fine
doStuff :: [Double]
doStuff = let inps = bar (Proxy :: Proxy N)
          in  map (mkFoo :: Foo N) inps

But now I want to be able to adjust N during runtime by loading information from a file, or from command line arguments.

I tried doing it by calling reflectNat:

doStuff :: Integer -> Double
doStuff n = reflectNat 5 $ \pn@(Proxy :: Proxy n) ->
              let inps = bar (Proxy :: Proxy n)
              in  map (mkFoo :: Foo n) inps

But...bar and mkFoo require KnownNat (n * 3), but reflectNat just gives me KnownNat n.

Is there any way I can generalize the proof that reflectNat gives me to satisfy foo ?

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  • 6
    No, you can't. If you can give some more context about what you're trying to accomplish, someone may be able to help. – dfeuer Sep 29 '15 at 8:43
  • 2
    Try writing a Short, Self Contained, Correct (Compilable), Example (sscce.org), so we can try it ourselves. – Hjulle Sep 29 '15 at 15:51
  • @dfeuer added concrete examples with what I think are adequate explanations of motivations for design decisions. thanks! – Justin L. Sep 29 '15 at 17:37
  • Do you do heavy computation with Nat? If not, then singleton Peano naturals would be a much better choice. – András Kovács Sep 29 '15 at 17:47
  • Two critical things are missing with GHC.TypeLits: induction and the singleton versions of the builtin Nat type families. The latter could be implemented with unsafe tricks, but the former seems hopeless to me. – András Kovács Sep 29 '15 at 17:59

I post another answer as it is more direct, editing the previous won't make sense.

In fact using the trick (popularised if not invented by Edward Kmett), from reflections reifyNat:

{-# LANGUAGE DataKinds #-}
{-# LANGUAGE KindSignatures #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE FlexibleContexts #-}
import GHC.TypeLits
import Data.Proxy
import Unsafe.Coerce

newtype MagicNat3 r = MagicNat3 (forall (n :: Nat). KnownNat (n * 3) => Proxy n -> r)

trickValue :: Integer -> Integer
trickValue = (*3)

-- No type-level garantee that the function will be called with (n * 3)
-- you have to believe us
trick :: forall a n. KnownNat n => Proxy n -> (forall m. KnownNat (m * 3) => Proxy m -> a) -> a
trick p f = unsafeCoerce (MagicNat3 f :: MagicNat3 a) (trickValue (natVal p)) Proxy

test :: forall m. KnownNat (m * 3) => Proxy m -> Integer
test _ = natVal (Proxy :: Proxy (m * 3))

So when you run it:

λ *Main > :t trick (Proxy :: Proxy 4) test :: Integer
trick (Proxy :: Proxy 4) test :: Integer :: Integer
λ *Main > trick (Proxy :: Proxy 4) test :: Integer

The trick is based on the fact that in GHC the one member class dictionaries (like KnownNat) are represented by the member itself. In KnownNat situation it turns out to be Integer. So we just unsafeCoerce it there. Universal quantification makes it sound from the outside.

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  • Thanks for taking the time to answer. It's "sound", but it looks like this can only work if trickValue, the function, is the same as whatever type family you're applying to m in the type signature of trick (in this case, (*3)). As far as I can see, the compiler won't help me if i have trickValue = (*4) instead. Is there any formulation where I can't do something silly like this? – Justin L. Sep 30 '15 at 8:31
  • @JustinL. I'm afraid you'll need a fully dependent language there. Either you'd have inefficient Nat representation with singletons, or you have to use unsafeCoerce and verify the correctness by other means than type system. – phadej Sep 30 '15 at 15:41
  • So sad. Well, I think I can get V from linear to work with arbitrary peano nats that I can cook up or use from singletons, but I lose the nice type lits syntax. If only there was a way to have type lits also be polymorphic like term numerical lits. thanks for your patience and help! – Justin L. Sep 30 '15 at 21:14

So, three months later, I have been going back and forth on good ways to accomplish this, but I finally settled on an actual very succinct trick that doesn't require any throwaway newtypes; it involves using a Dict from the constraints library; you could easily write a:

natDict :: KnownNat n => Proxy n -> Dict (KnownNat n)
natDict _ = Dict

triple :: KnownNat n => Proxy n -> Dict (KnownNat (n * 3))
triple p = reifyNat (natVal p * 3) $
             \p3 -> unsafeCoerce (natDict p3)

And once you get Dict (KnownNat (n * 3), you can pattern match on it to get the (n * 3) instance in scope:

case triple (Proxy :: Proxy n) of
  Dict -> -- KnownNat (n * 3) is in scope

You can actually set these up as generic, too:

addNats :: (KnownNat n, KnownNat m) => Proxy n -> Proxy m -> Dict (KnownNat (n * m))
addNats px py = reifyNat (natVal px + natVal py) $
                  \pz -> unsafeCoerce (natDict pz)

Or, you can make them operators and you can use them to "combine" Dicts:

infixl 6 %+
infixl 7 %*
(%+) :: Dict (KnownNat n) -> Dict (KnownNat m) -> Dict (KnownNat (n + m))
(%*) :: Dict (KnownNat n) -> Dict (KnownNat m) -> Dict (KnownNat (n * m))

And you can do things like:

case d1 %* d2 %+ d3 of
  Dict -> -- in here, KnownNat (n1 * n2 + n3) is in scope

I've wrapped this up in a nice library, typelits-witnesses that I've been using. Thank you all for your help!

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Your question isn't very descriptive, so I'll try my best to feel blanks:

Let's assume that Blah n is Proxy n.

I also assume that reflectNat is a way to call universally quantified (over typelevel Nat) function, using term-level natural number.

I don't know better way than writing your own reflectNat providing that

{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE KindSignatures #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE FlexibleContexts #-}
import GHC.TypeLits
import Data.Proxy

data Vec a (n :: Nat) where
  Nil  :: Vec a 0
  Cons :: a -> Vec a n -> Vec a (1 + n)

vecToList :: Vec a n -> [a]
vecToList Nil = []
vecToList (Cons h t) = h : vecToList t

repl :: forall n a. KnownNat n => Proxy n -> a -> Vec a n
repl p x = undefined -- this is a bit tricky with Nat from GHC.TypeLits, but possible

foo :: forall (n :: Nat). KnownNat (1 + n) => Proxy n -> Vec Bool (1 + n)
foo _ = repl (Proxy :: Proxy (1 + n)) True

-- Here we have to write our own version of 'reflectNat' providing right 'KnownNat' instances
-- so we can call `foo`
reflectNat :: Integer -> (forall n. KnownNat (1 + n) => Proxy (n :: Nat) -> a) -> a
reflectNat = undefined

test :: [Bool]
test = reflectNat 5 $ \p -> vecToList (foo p)

Alternatively, using singletons you can use SomeSing. Then types will be different

reflectNat :: Integer -> (forall (n :: Nat). SomeSing (n :: Nat) -> a) -> a

I.e. instead of magic dict KnownNat you have concrete singleton value. Thus in foo you'd need to construct SomeSing (1 + n) explicitly, given SomeSing n -- which is quite simple.

In run-time both KnownNat dictionary and SomeSing value will be passed around carring the number value, and explicit is IMHO better in this situation.p)

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  • It looks like reflectNat's definition in reflections is basically similar (it uses unsafeCoerce), so this might be an okay road to go down :) I'll look into singletons...do you know how I'd write reflectNat in singletons fashion? Sing Nat seems to provide something that I can't pattern match on/a single constructor like Proxy, so I'm not sure how to wrangle with it. – Justin L. Sep 29 '15 at 17:40
  • Can't say about singleton-2.0 as there aren't haddocks online, but for singletons- seems that it uses SNat :: KnownNat n => Sing Nat n - so actually no difference. I was in my simple PeanoNat world :( – phadej Sep 29 '15 at 18:38

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