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# Type Inference for declared instance

I came up with a nice exercise, but can't make it work.

The idea is to try and express Roman numerals in such a way that the type checker will tell me whether the numeral is valid.

``````    {-# LANGUAGE RankNTypes
, MultiParamTypeClasses #-}

data One a b c = One a deriving (Show, Eq)
data Two a b c = Two (One a b c) (One a b c) deriving (Show, Eq)
data Three a b c = Three (One a b c) (Two a b c) deriving (Show, Eq)
data Four a b c = Four (One a b c) (Five a b c) deriving (Show, Eq)
data Five a b c = Five b deriving (Show, Eq)
data Six a b c = Six (Five a b c) (One a b c) deriving (Show, Eq)
data Seven a b c = Seven (Five a b c) (Two a b c) deriving (Show, Eq)
data Eight a b c = Eight (Five a b c) (Three a b c) deriving (Show, Eq)
data Nine a b c d e = Nine (One a b c) (One c d e) deriving (Show, Eq)

data Z = Z deriving (Show, Eq) -- dummy for the last level
data I = I deriving (Show, Eq)
data V = V deriving (Show, Eq)
data X = X deriving (Show, Eq)
data L = L deriving (Show, Eq)
data C = C deriving (Show, Eq)
data D = D deriving (Show, Eq)
data M = M deriving (Show, Eq)

i :: One I V X
i = One I

v :: Five I V X
v = Five V

x :: One X L C
x = One X

l :: Five X L C
l = Five L

c :: One C D M
c = One C

d :: Five C D M
d = Five D

m :: One M Z Z
m = One M

infixr 4 #

class RomanJoiner a b c where
(#) :: a -> b -> c

instance RomanJoiner (One a b c) (One a b c) (Two a b c) where
(#) = Two

instance RomanJoiner (One a b c) (Two a b c) (Three a b c) where
(#) = Three

instance RomanJoiner (One a b c) (Five a b c) (Four a b c) where
(#) = Four

instance RomanJoiner (Five a b c) (One a b c) (Six a b c) where
(#) = Six

instance RomanJoiner (Five a b c) (Two a b c) (Seven a b c) where
(#) = Seven

instance RomanJoiner (Five a b c) (Three a b c) (Eight a b c) where
(#) = Eight

instance RomanJoiner (One a b c) (One c d e) (Nine a b c d e) where
(#) = Nine

main = print \$ v # i # i
``````

This possibly can be done differently, and the solution is incomplete, but right now I need to understand why it complains that there is no instance for RomanJoiner (One I V X) (One I V X) b0, whereas I think I declared such a joiner.

-

The issue is that instances are not chosen based on the only one that works: one extension `FunctionalDependencies` helps to get some more type inference. Enabling that, and saying with `| a b -> c` that the type of `a # b` can be inferred from the types of `a` and `b`. Unfortunately, that's not the only thing you have to do because you'd get the error `Functional dependencies conflict between instance declarations`. Using some classes defined in HList (these could be defined anywhere else), the conflicting two instances can be combined into a single one, where the two (or 3 if you count an error) possible results are chosen based on whether some types are equal.

1. you don't have to replicate what's going on at the type level at the value level again (`hCond` vs `HCond`) if you had lazier Show instances (like ```instance Show I where show _ = "I"```).
2. with more modern extension `TypeFamilies` many of those intermediate type variables `ba, bb, bc, babc ...` can be eliminated.

``````{-# LANGUAGE RankNTypes, MultiParamTypeClasses, FunctionalDependencies, ScopedTypeVariables, UndecidableInstances, FlexibleContexts, FlexibleInstances #-}
import Data.HList hiding ((#))
import Data.HList.TypeEqGeneric1
import Data.HList.TypeCastGeneric1
import Unsafe.Coerce

data One a b c = One a deriving (Show, Eq)
data Two a b c = Two (One a b c) (One a b c) deriving (Show, Eq)
data Three a b c = Three (One a b c) (Two a b c) deriving (Show, Eq)
data Four a b c = Four (One a b c) (Five a b c) deriving (Show, Eq)
data Five a b c = Five b deriving (Show, Eq)
data Six a b c = Six (Five a b c) (One a b c) deriving (Show, Eq)
data Seven a b c = Seven (Five a b c) (Two a b c) deriving (Show, Eq)
data Eight a b c = Eight (Five a b c) (Three a b c) deriving (Show, Eq)
data Nine a b c d e = Nine (One a b c) (One c d e) deriving (Show, Eq)

data Z = Z deriving (Show, Eq) -- dummy for the last level
data I = I deriving (Show, Eq)
data V = V deriving (Show, Eq)
data X = X deriving (Show, Eq)
data L = L deriving (Show, Eq)
data C = C deriving (Show, Eq)
data D = D deriving (Show, Eq)
data M = M deriving (Show, Eq)

i :: One I V X
i = One I

v :: Five I V X
v = Five V

x :: One X L C
x = One X

l :: Five X L C
l = Five L

c :: One C D M
c = One C

d :: Five C D M
d = Five D

m :: One M Z Z
m = One M

infixr 4 #

class RomanJoiner a b c | a b -> c where
(#) :: a -> b -> c

instance RomanJoiner (One a b c) (Two a b c) (Three a b c) where
(#) = Three

instance RomanJoiner (One a b c) (Five a b c) (Four a b c) where
(#) = Four

instance RomanJoiner (Five a b c) (One a b c) (Six a b c) where
(#) = Six

instance RomanJoiner (Five a b c) (Two a b c) (Seven a b c) where
(#) = Seven

instance RomanJoiner (Five a b c) (Three a b c) (Eight a b c) where
(#) = Eight

data Error = Error
instance forall a b c a' b' c' ba bb bc bab babc z bn nine.
(TypeEq a a' ba,
TypeEq b b' bb,
TypeEq c c' bc,
HAnd ba bb bab,
HAnd bab bc babc,

TypeEq c a' bn,
HCond bn (Nine a b c b' c') Error nine,

HCond babc (Two a b c) nine  z) =>
RomanJoiner (One a b c) (One a' b' c') z where
(#) x y = hCond (undefined :: babc)
(Two (uc x :: One a b c) (uc y :: One a b c)) \$
hCond (undefined :: bn)
(Nine (uc x :: One a b c) (uc y :: One c b' c'))
Error
where uc = unsafeCoerce

main = print \$ v # i # i
{-
Prints with ghc 762, HList-0.2.3

*Main> main
Seven (Five V) (Two (One I) (One I)

-}
``````
-
Thanks. It is not clear why you needed to treat Two specially, but not the rest of it. Does this mean other numerals will need special treatment of others, too? I'll need to digest the solution. – Sassa NF Aug 14 '13 at 20:21