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Could someone please explain why this compiles

Prelude> 1 :: Num a => a

and this doesn't

Prelude> 1.0 :: Num a => a

Second example would work with Fractional, but Num is superclass of Fractional. Just like it's superclass of Integral.

3 Answers 3

5

If we have

x :: Num a => a

the user of x can pick a as wanted. E.g.

x :: Int

What would this evaluate to if x = 1.5 ?

For this reason a floating point literal can't be given the polytype Num a => a, since its value won't (in general) fit all Numeric types.

Integral literals instead fit every numeric type, so they are allowed.

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  • thanks @chi. makes sense when you put it that way :) so 1 :: Num a => a holds true for any a that's instance of Num, but 1.0 doesn't.
    – rodic
    Feb 11, 2017 at 13:04
  • 2
    @rodic Yes. Theoretically, the designers of Haskell could have mandated that 1.0 be handled as if it were 1, but in practice it would be terribly confusing to discover that, in a given context, 1.0 type checks but 1.5 does not. So, 1.0 was allowed only to represent values of types in the Fractional typeclass.
    – chi
    Feb 11, 2017 at 13:18
  • yeah, i had any float on mind when i wrote 1.0. but now i realize my original question could be rewritten like, why 1 :: a doesn't compile. thanks a lot for the help.
    – rodic
    Feb 11, 2017 at 13:21
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The superclass relationship between type classes does not establish relationships between types. It tells us only that if type t is a member of type class C, and B is a super class of C, then t will also be member of B.

It doesn't say that each value v::t can be used at any type that is also member of B. But this is what you are stating with:

3.14159 :: Num a => a
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It's important to distinguish between polymorphism in OO languages and polymorphism in Haskell. OO polymorphism is covariant, while Haskell's parametric polymorphism is contravariant.

What this means is: in an OO language, if you have

class A {...}
class B: A {...}

i.e. A is a superclass of B, then any value of type B is also a value of type A. (Note that any particular value is actually not polymorphic but has a concrete type!) Thus, if you had

class Num {...}
class Fractional: Num {...}

then a Fractional value could indeed be used as a Num value. That's roughly what covariant means: any subclass value is also a superclass value; the values hierarchy goes the same direction as the type hierarchy.

In Haskell, classes are different. There is no such thing as a “value of type Num”, only values of concrete types a. That type may be in the Num class.

Unlike in OO languages, a value like 1 :: Num a => a is polymorphic: it can take on whatever type the environment demands, provided the type is in the Num class. (Actually that syntax is just shorthand for 1 :: ∀ a . Num a => a, to be read as “for all types a, you can have a value 1 of type a.) For example,

Prelude> let x = 1 :: Num a => a
Prelude> x :: Int
1
Prelude> x :: Double
1.0

You can also give x a more specific constraint of Fractional, since that's a subclass of Num. That just restricts what type the polymorphic value can be instantiated to:

Prelude> let x = 1 :: Fractional a => a
Prelude> x :: Int

<interactive>:6:1:
    No instance for (Fractional Int) arising from a use of ‘x’
    ...
Prelude> x :: Double
1.0

because Int is not a fractional type.

Thus, Haskell's polymorphism is contravariant: polymorphic values restricted to a superclass can also be restricted to a subclass instead, but not the other way around. In particular, you can obviously have

Prelude> let y = 1.0 :: Fractional a => a

(y is the same as x'), but you can not generalise this to y' = 1.0 :: Num a => a. Which is a good thing as Ingo remarked since otherwise it would be possible to do

Prelude> 3.14159 :: Int
  ????
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  • got it. num is not a type like in oo, but set of types and in order for a val to be polymorphic it must be able to instantiate to any num type, any other rule would lead to absurd situations as you guys showed.
    – rodic
    Feb 11, 2017 at 15:06

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