They're not strange, they're simply *coinductive* naturals. Leaving aside the issue of ⊥, we can define the natural number type here as consisting of either `Zero`

, or `Succ`

applied to a natural number. An inductive definition would assume a well-defined end, i.e., that any number starts from a `Zero`

constructor. The coinductive definition merely says that given any natural number, it will either be `Zero`

or we can remove the outer `Succ`

to get another natural number.

The seemingly subtle difference there is that the coinductive definition includes an endless series of `Succ`

constructors, which really is a true representation of infinity. This is meaningful because, while an inductive definition is about ensuring that recursion will reach a well-defined base case, coinductive definitions are about ensuring that there will always be a well-define next step available.

The coinductive interpretation is convenient and in some ways obligatory in Haskell, due to data constructors being lazy.

So, this infinite number really is infinity, or ω if you need to specify which infinity, as Daniel Fischer said. It's just a coinductive infinity, much like the infinite lists that are more commonly encountered.

If you think of natural numbers via their church encoding, finite numbers mean "iterate this function N times"; ω means "iterate this function indefinitely".