Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# Applying a fixed-length-vector-function to the inital part of a longer fixed-length-vector

I have the following definition of fixed-length-vectors using ghcs extensions `GADTs`, `TypeOperators` and `DataKinds`:

``````data Vec n a where
T    :: Vec VZero a
(:.) :: a -> Vec n a -> Vec (VSucc n) a

infixr 3 :.

data VNat  =  VZero |  VSucc VNat  -- ... promoting Kind VNat

type T1 = VSucc VZero
type T2 = VSucc T1
``````

and the following defiition of a TypeOperator `:+`:

``````type family (n::VNat) :+ (m::VNat) :: VNat
type instance VZero :+ n = n
type instance VSucc n :+ m = VSucc (n :+ m)
``````

For my whole intented library to make sense, I need to apply a fixed-length-vector-function of type `(Vec n b)->(Vec m b)` to the inial part of a longer vector `Vec (n:+k) b`. Let's call that function `prefixApp`. It should have type

``````prefixApp :: ((Vec n b)->(Vec m b)) -> (Vec (n:+k) b) -> (Vec (m:+k) b)
``````

Here's an example application with the fixed-length-vector-function `change2` defined like this:

``````change2 :: Vec T2 a -> Vec T2 a
change2 (x :. y :. T) = (y :. x :. T)
``````

`prefixApp` should be able to apply `change2` to the prefix of any vector of length >=2, e.g.

``````Vector> prefixApp change2 (1 :. 2 :. 3 :. 4:. T)
(2 :. 1 :. 3 :. 4 :. T)
``````

Has anyone any idea how to implement `prefixApp`? (The problem is, that a part of the type of the fixed-length-vector-function has to be used to grab the prefix of the right size...)

Edit: Daniel Wagners (very clever!) solution seems to have worked with some release candidate of ghc 7.6 (not an official release!). IMHO it shouldnt work, however, for 2 reasons:

1. The type-declaration for `prefixApp` lacks an `VNum m` in the context (for `prepend (f b)` to typecheck correctly.
2. Even more problematic: ghc 7.4.2 does not assume the TypeOperator `:+` to be injective in its first argument (nor the second, but thats not essential here), which leads to a type error: from the type-declaration, we know that `vec` must have type `Vec (n:+k) a` and the type-checker infers for the expression `split vec` on the right-hand side of the definition a type of `Vec (n:+k0) a`. But: the type-checker cannot infer that `k ~ k0` (since there is no assurance that `:+` is injective).

Does anyone know a solution to this second issue? How can I declare `:+` to be injective in its first argument and/or how can I avoid running into this issue at all?

-
It seems like this should be possible with type classes and functional dependencies. Unfortunately, my prototype code seems to have arisen a bug in GHC, so I can't test it. – gereeter Sep 6 '12 at 2:58
@gereeter: Yes, I agree that it should be (in theory!) be possible with functional dependencies, which was actually my first approach. Unfortunately, it didnt work for reasons which are not clear to me. Nevertheless, I would be interested in solution which uses functional dependencies... – phynfo Sep 6 '12 at 22:54

Here is a version where split is not in a type class. Here we build a singleton type for natural numbers (SN), which enables to pattern match on `n' in the definition of split'. This extra argument can then be hidden by the use of a type class (ToSN).

The type Tag is used to manually specify the non-inferred arguments.

(this answer has been co-authored with Daniel Gustafsson)

Here is the code:

``````{-# LANGUAGE TypeFamilies, TypeOperators, DataKinds, GADTs, ScopedTypeVariables, FlexibleContexts #-}
module Vec where
data VNat = VZero | VSucc VNat  -- ... promoting Kind VNat

data Vec n a where
T    :: Vec VZero a
(:.) :: a -> Vec n a -> Vec (VSucc n) a·

infixr 3 :.

type T1 = VSucc VZero
type T2 = VSucc T1

data Tag (n::VNat) = Tag

data SN (n::VNat) where
Z :: SN VZero
S :: SN n -> SN (VSucc n)

class ToSN (n::VNat) where
toSN :: SN n

instance ToSN VZero where
toSN = Z

instance ToSN n => ToSN (VSucc n) where
toSN = S toSN

type family (n::VNat) :+ (m::VNat) :: VNat
type instance VZero :+ n = n
type instance VSucc n :+ m = VSucc (n :+ m)

split' :: SN n -> Tag m -> Vec (n :+ m) a -> (Vec n a, Vec m a)
split' Z     _ xs = (T , xs)
split' (S n) _ (x :. xs) = let (as , bs) = split' n Tag xs in (x :. as , bs)

split :: ToSN n => Tag m -> Vec (n :+ m) a -> (Vec n a, Vec m a)
split = split' toSN

append :: Vec n a -> Vec m a -> Vec (n :+ m) a
append T ys = ys
append (x :. xs) ys = x :. append xs ys

prefixChange :: forall a m n k. ToSN n => (Vec n a -> Vec m a) -> Vec (n :+ k) a -> Vec (m :+ k) a
prefixChange f xs = let (as , bs) = split (Tag :: Tag k) xs in append (f as) bs
``````
-
Splendid approach! Works really well and I even can define a `tailApp` function with this technique. Unfortunately, further abstraction seems to overstrain Haskell's type system, e.g. I could'nt define a `(***)`-function with `prefixApp` and `tailApp` like `(***) f g = prefixApp f . tailApp g`. Well, maybe it's just too much dependent typing for a non-dependent-typed language like Haskell... – phynfo Sep 7 '12 at 21:04

Make a class:

``````class VNum (n::VNat) where
split   :: Vec (n:+m) a -> (Vec n a, Vec m a)
prepend :: Vec n a -> Vec m a -> Vec (n:+m) a

instance VNum VZero where
split     v = (T, v)
prepend _ v = v

instance VNum n => VNum (VSucc n) where
split   (x :. xs)   = case split xs of (b, e) -> (x :. b, e)
prepend (x :. xs) v = x :. prepend xs v

prefixApp :: VNum n => (Vec n a -> Vec m a) -> (Vec (n:+k) a -> (Vec (m:+k) a))
prefixApp f vec = case split vec of (b, e) -> prepend (f b) e
``````
-
Thanks, Daniel, for the very nice answer! (Honestly, I thought, there would be no def for `prefixApp`). But: Doesnt the context of your type-declaration of `prefixApp` miss an additional `VNum m` (for `prepend (f b) e` to be typechecked correctly? And perhaps an additional VNum `(n:+k)` for `split vec` to be typechecked correctly? – phynfo Sep 1 '12 at 11:31
A second issue is that the type-checker claims the following problem: `vec` has type `Vec (n:+k) a` (following from the left-hand-side of the `prefixApp` definition) and the type-checker infers from the expression `split vec` a type of `Vec (n:+k0) a`. But: the type-checker cant infer that `k~k0` since there is no assurance that the type-function `:+` is injective, which seems sound for me, because I never declared `:+` to be injective. Is there a possibility to tell ghc that `:+` should be injective in both its first and second argument? – phynfo Sep 1 '12 at 11:42
@phynfo Hm. I checked that GHC 7.6 accepted this definition and called it a day, but you raise some pretty reasonable objections; now I don't understand why it was accepted. – Daniel Wagner Sep 1 '12 at 16:31
I run ghc 7.4.1. Is ghc 7.6. an official release? – phynfo Sep 1 '12 at 18:47
@phynfo Not yet, there's only a release candidate. – Daniel Wagner Sep 1 '12 at 20:58

If you can live with a slightly different type of prefixApp:

``````{-# LANGUAGE GADTs, TypeOperators, DataKinds, TypeFamilies #-}

import qualified Data.Foldable as F

data VNat  =  VZero |  VSucc VNat  -- ... promoting Kind VNat

type T1 = VSucc VZero
type T2 = VSucc T1
type T3 = VSucc T2

type family (n :: VNat) :+ (m :: VNat) :: VNat
type instance VZero :+ n = n
type instance VSucc n :+ m = VSucc (n :+ m)

type family (n :: VNat) :- (m :: VNat) :: VNat
type instance n :- VZero = n
type instance VSucc n :- VSucc m = n :- m

data Vec n a where
T    :: Vec VZero a
(:.) :: a -> Vec n a -> Vec (VSucc n) a

infixr 3 :.

-- Just to define Show for Vec
instance F.Foldable (Vec n) where
foldr _ b T = b
foldr f b (a :. as) = a `f` F.foldr f b as

instance Show a => Show (Vec n a) where
show = show . F.foldr (:) []

class Splitable (n::VNat) where
split :: Vec k b -> (Vec n b, Vec (k:-n) b)

instance Splitable VZero where
split r = (T,r)

instance Splitable n => Splitable (VSucc n) where
split (x :. xs) =
let (xs' , rs) = split xs
in ((x :. xs') , rs)

append :: Vec n a -> Vec m a -> Vec (n:+m) a
append T r = r
append (l :. ls) r = l :. append ls r

prefixApp :: Splitable n => (Vec n b -> Vec m b) -> Vec k b -> Vec (m:+(k:-n)) b
prefixApp f v = let (v',rs) = split v in append (f v') rs

-- A test
inp :: Vec (T2 :+ T3) Int
inp = 1 :. 2 :. 3 :. 4:. 5 :. T

change2 :: Vec T2 a -> Vec T2 a
change2 (x :. y :. T) = (y :. x :. T)

test = prefixApp change2 inp -- -> [2,1,3,4,5]
``````

In fact, your original signature can also be used (with augmented context):

``````prefixApp :: (Splitable n, (m :+ k) ~ (m :+ ((n :+ k) :- n))) =>
((Vec n b)->(Vec m b)) -> (Vec (n:+k) b) -> (Vec (m:+k) b)
prefixApp f v = let (v',rs) = split v in append (f v') rs
``````

Works in 7.4.1

Upd: Just for fun, the solution in Agda:

``````data Nat : Set where
zero : Nat
succ : Nat -> Nat

_+_ : Nat -> Nat -> Nat
zero + r = r
succ n + r = succ (n + r)

data _*_ (A B : Set) : Set where
_,_ : A -> B -> A * B

data Vec (A : Set) : Nat -> Set where
[] : Vec A zero
_::_ : {n : Nat} -> A -> Vec A n -> Vec A (succ n)

split : {A : Set}{k n : Nat} -> Vec A (n + k) -> (Vec A n) * (Vec A k)
split {_} {_} {zero} v = ([] , v)
split {_} {_} {succ _} (h :: t) with split t
... | (l , r) = ((h :: l) , r)

append : {A : Set}{n m : Nat} -> Vec A n -> Vec A m -> Vec A (n + m)
append [] r = r
append (h :: t) r with append t r
... | tr = h :: tr

prefixApp : {A : Set}{n m k : Nat} -> (Vec A n -> Vec A m) -> Vec A (n + k) -> Vec A (m + k)
prefixApp f v with split v
... | (l , r) = append (f l) r
``````
-
Wow, really cute solution using a second TypeOperator `:-`; I really like it! Unfortunatly, the type signatures get a bit harder to read. It would be nice to be able to teach ghc how to calculate with `:+`and `:-` in an axiomatic way -- just like you did it for a single case in the context of `prefixApp`, telling ghc that `m:+k` is equal to `m:+((n:+k):-n`. – phynfo Sep 4 '12 at 21:11
Note that there is a `toList` function already defined for foldable instances, so one doesn't need to have the separate `F.foldr (:) []`. – huon Sep 5 '12 at 8:48
@phynfo Even if there is a way it is definitely not the most trivial. Probably because Haskell is not a dependent type language. On the other hand in Agda, for example, the solution for your task is straightforward (see my update). – Ed'ka Sep 6 '12 at 15:42
@Ed'ka: You are right and I would really like to use Agda. However, I need Haskell's ability to define contructor classes at the same time. As far as I understood it, Adga is not able to handle constructor classes. Really a shame. – phynfo Sep 7 '12 at 21:07
@phynfo: I believe that with the latest version of Agda (2.3.0) Haskell's type classes can be emulated: wiki.portal.chalmers.se/agda/… – Ed'ka Sep 10 '12 at 0:52