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For example, Num a => a.

I assumed they're just called "constrained types", but Googling didn't turn up many uses of that term so I'm curious to know if they go by some other name.

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I'm not into haskell, but are you talking about enumerable types? – Simon Forsberg Jul 13 '12 at 16:45
@SimonAndréForsberg No, he's not. What makes you think of enums here? He's talking about type constraints like <T extends Foobar> in Java. – sepp2k Jul 13 '12 at 16:50
@sepp2k I interpreted "types with type constraints" as "types which are allowed only to have one of specific values". Thanks for the Java example, that's my kind of language ;) – Simon Forsberg Jul 13 '12 at 16:53
Ok then, another attempt (my second and last attempt): Are you talking about "generics"? en.wikipedia.org/wiki/Generic_programming – Simon Forsberg Jul 13 '12 at 16:56
I thought the "haskell" tag would be enough to indicate that I'm talking about something in Haskell, not Java. :-) – Laurence Gonsalves Jul 13 '12 at 18:07
up vote 6 down vote accepted

"Qualified types". See Mark P. Jones. Qualified Types: Theory and Practice. Cambridge University Press, Cambridge, 1994.

Plenty of relevant matches on Google.

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Types with this particular kind of constraints are called "qualified types", and the feature itself sometimes "qualified polymorphism". I believe the terminology was originally introduced by Mark Jones' ESOP '92 paper.

Qualified types should not be confused with the more mainstream notion of "bounded polymorphism", on which generics in languages like Java are based. Bounded polymorphism essentially is the (rather complicated) combination of parametric polymorphism with subtyping, whereas qualified types get along without subtyping.

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I'm no type theory expert, but with a little research, this is what I've found (which may or may not be helpful, but I can't fit this in a comment).

A Gentle Introduction to Haskell: Classes calls the Num a portion the type's context:

The constraint that a type a must be an instance of the class Eq is written Eq a. Thus Eq a is not a type expression, but rather it expresses a constraint on a type, and is called a context.

So I suppose you could say "a type with a context", or as you mentioned "constrained type".

Another place to look is where type-classes are first described (I believe) for Haskell: How to make ad-hoc polymorphism less ad-hoc [postscript].

Type classes appear to be closely related to issues that arise in object-oriented programming, bounded quantification of types, and abstract data types[CW85, MP85, Rey85]. Some of the connections are outlined below, but more work is required to under-stand these relations fully.

This paper was written in 1988, so I'm not sure if these relations are now fully understood, but the wikipedia page for Bounded quantification doesn't mention Haskell, so I'm not sure it's exactly the same thing. (once again, not a type theorist -- just a guy who likes Haskell)

Also, about the type square :: Num a => a -> a it says:

This is read, "square has type a -> a, for every a such that a belongs to class Num (i.e., such that (+),(*), and negate are defined on a)."

You could say the type "belongs to a class".

That's about all I've got. Personally, I think "constrained types" or "types constrained to a class" work fine.

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Regarding the relationship between OOP and bounded quantification: stackoverflow.com/questions/2707171/… – Heatsink Jul 13 '12 at 20:29
@Heatsink Thanks. – Adam Wagner Jul 13 '12 at 20:52

The Num a => part is indeed called a constraint; you can read it as "if Num a is true, then ..."

Normally, constraints and quantifiers are discussed together. Any constrained type can be converted to an equivalent type where constraints only appear just inside forall or exists quantifiers. So, you won't hear of "constrained types" as often as you will hear of "constrained parametric polymorphism" (forall a. C => T), "constrained existential types" (exists a. C => T), or "constrained polymorphism" (both kinds of quantifiers).

A related term is "bounded polymorphism." Bounded polymorphism usually means constrained polymorphism where the constraint is a subtype or supertype constraint. However, this distinction isn't strictly followed. In languages with subtyping like Java or Scala, you will often hear any kind of constraint called a "bound."

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When I ask ghci for the type of 5 it says 5 :: (Num t) => t. Are you saying that that's actually a forall or exists? If so, which one? – Laurence Gonsalves Jul 14 '12 at 17:21
@LaurenceGonsalves That type is forall t. (Num t) => t. Free variables in types are implicitly quantified with forall. There is no exists keyword; existential types only occur in combination with data constructors. – Heatsink Jul 14 '12 at 18:06

You could call it a bounded polymorphic type (see wikipedia).

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The phrase "universal or existential quantifiers which are restricted ("bounded") to range only over the subtypes of a particular type" on that page leaves me skeptical. Even though Haskell typeclasses seem pretty similar to interfaces in Java, I don't think what they provide really constitutes "subtyping". If they were subtypes, then that would mean the type system violates LSP. For example, the >>= method of Monad and the == method of Eq both have methods that take parameters that are "more specific" in their instances. – Laurence Gonsalves Jul 13 '12 at 17:50
I agree, Haskell certainly doesn't have subtyping (for which this term is actually used.) Still, it looks similar to me if you actually think of it as literal "bounded quantification": forall a. a<:T => ... is just a kind of a predicate in the quantifier, similar to forall a. N(a) => ... (thinking in predicate logic here). Maybe a better expression would be "class-bounded polymorphic type". But here, I'd find the simple "constrained type" much simple. – phg Jul 13 '12 at 18:36

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