Apologies in advance if this question is a bit vague. It's the result of some weekend daydreaming.

With Haskell's wonderful type system, it's delightfully pleasing to express mathematical (especially algebraic) structure as typeclasses. I mean, just have a look at numeric-prelude! But taking advantage of such wonderful type structure in practice has always seemed difficult to me.

You have a nice, type-system way of expressing that `v1`

and `v2`

are elements of a vector space `V`

and that `w`

is a an element of a vector space `W`

. The type system lets you write a program adding `v1`

and `v2`

, but not `v1`

and `w`

. Great! But in practice you might want to play with potentially hundreds of vector spaces, and you certainly don't want to create types `V1`

, `V2`

, ..., `V100`

and declare them instances of the vector space typeclass! Or maybe you read some data from the real world resulting in symbols `a`

, `b`

and `c`

- you may want to express that the free vector space over these symbols really is a vector space!

So you're stuck, right? In order to do many of the things you'd like to do with vector spaces in a scientific computing setting, you have to give up your typesystem by foregoing a vector space typeclass and having functions do run-time compatibility checks instead. Should you have to? Shouldn't it be possible to use the fact that Haskell is purely functional to write a program that generates all the types you need and inserts them into the real program? Does such a technique exist? By all means do point out if I'm simply overlooking something basic here (I probably am) :-)

**Edit:** Just now did I discover fundeps. I'll have to think a bit about how they relate to my question (enlightening comments with regards to this are appreciated).