I'm interested in generalizing some computational tools to use a Cayley Table, meaning a lookup table based multiplication operation.

I could create a minimal implementation as follows :

```
date CayleyTable = CayleyTable {
ct_name :: ByteString,
ct_products :: V.Vector (V.Vector Int)
} deriving (Read, Show)
instance Eq (CayleyTable) where
(==) a b = ct_name a == ct_name b
data CTElement = CTElement {
ct_cayleytable :: CayleyTable,
ct_index :: !Int
}
instance Eq (CTElement) where
(==) a b = assert (ct_cayleytable a == ct_cayleytable b) $
ct_index a == ct_index b
instance Show (CTElement) where
show = ("CTElement" ++) . show . ctp_index
a **** b = assert (ct_cayleytable a == ct_cayleytable b) $
((ct_cayleytable a) ! a) ! b
```

There are however numerous problems with this approach, starting with the run time type checking via `ByteString`

comparisons, but including the fact that `read`

cannot be made to work correctly. Any idea how I should do this correctly?

I could imagine creating a family of newtypes `CTElement1`

, `CTElement2`

, etc. for `Int`

with a `CTElement`

typeclass that provides the multiplication and verifies their type consistency, except when doing IO.

Ideally, there might be some trick for passing around only one copy of this `ct_cayleytable`

pointer too, perhaps using an implicit parameter like `?cayleytable`

, but this doesn't play nicely with multiple incompatible Cayley tables and gets generally obnoxious.

Also, I've gathered that an index into a vector can be viewed as a comonad. Is there any nice comonad instance for vector or whatever that might help smooth out this sort of type checking, even if ultimately doing it at runtime?

`Eq CayleyTable`

faster because the Cayley table might have millions entries. An`Int`

works fine too. Ideally,`Read`

should learn the specific Cayley table from the type system, presumably`read "0" :: CTElementFoo`

should always return a reasonable value, or perhaps using 1 instead if indices are 1 based. – Jeff Burdges Feb 15 '12 at 12:20