# Is coproduct the same as sum types?

I was watching this lecture from Bartosz Milewski and he was explaining coproduct and sum types.

On the lecture, He went from one to the other.

Is the coproduct the same as the sum type?

Basically, yes. Coproducts are in principle more general, but that needn't necessarily concern you as far as Haskell is concerned.

An example of a category where the coproduct is not a sum type is the category of vector spaces with linear mappings as the arrows. In this category, disjoint-sum types don't make a lot of sense because they would give you two different zero-vector elements.

Instead, it turns out that product types (which in linear algebra are called direct sums, but implementation-wise they're tuples, not alternatives) are a coproduct on this category:

``````type LFun v w = v -> w

initial :: VectorSpace w => LFun () w
initial () = zeroV

(+++) :: VectorSpace w => LFun u w -> LFun v w -> LFun (u,v) w
(f+++g) (u,v) = f u ^+^ g v
``````

(The standard product on this category is then the tensor product. Though it's possible to ignore this and use ordinary tuples as the product type, i.e. the actual coproducts. I think this has to do with the fact that any Hilbert space is isomorphic to its dual space. In my `constrained-categories`/`linearmap-category` library, the products are tuples, whereas Mike Izbicki has not done this in the topically similar `SubHask` library.)See Derek Elkins' comment.

I understand “sum type” in the data sense, i.e. as an algebraic data type with structure of a tagged union.

• Perhaps poser would be a easier and more interesting example. Commented Apr 23, 2017 at 16:17
• Posets you mean, I take it? They're easier, arguably, much less interesting. But if you add them as an extra example, certainly couldn't cause any harm. Commented Apr 23, 2017 at 16:25
• Yes (sorry stupid typo). More interesting because sums and products there have nothing to do with set-theoretical sums and products. In vector spaces you still kinda have set-theoretical sums and products (over sets of indices, when you fix a base for each space). This is my possibly incorrect understanding anyway. Commented Apr 23, 2017 at 17:01
• Ah, that's what you mean. Yes, sets of indices are a possible interpretation that matches the sum and product notion, though I'm personally not a fan of this interpretation because in general, a vector space doesn't have a canonical basis. Commented Apr 23, 2017 at 17:18
• Categorically, there is no definition of "sum type" except for coproduct, so the statement like "the coproduct is not a sum type" is a bit nonsensical. I think what you are effectively trying to say is that the underlying set of the coproduct is not the disjoint union of the underlying set of the summands. Also, the category of vector spaces does have categorical products. They happen to coincide with coproducts in the finite case (and this is called a biproduct). They diverge when you consider co/products indexed by infinite sets. Tensor products are something else entirely, categorically. Commented Apr 24, 2017 at 3:16