These are all examples of "class constraints": they constrain what types can be used in place of the type variable which follows them (`a`

in this case), requiring that it belong to a particular type class. `Ord`

, `Eq`

and `Num`

are examples of type classes.

`Ord a => ...`

means `a`

is a type which has a natural notion of order associated with it. For example, integers can be naturally arranged from smaller to larger. In mathematical terms, there exists a total order on `a`

. An obvious example a function which requires this constraint is `sort :: Ord a => [a] -> [a]`

; read this signature as saying that `sort`

only works on lists of things which can be put in order relative to one another.

`Eq a => ...`

means `a`

is a type whose members can be compared to each other for some notion of equality. In mathematical terms, there exists an equivalence relation on `a`

. Note that this is a superclass of `Ord`

, meaning anything that has a notion of ordering must also have a notion of equivalence. An example of a function which requires this constraint is `elem :: Eq a => a -> [a] -> Bool`

(which determines if a list contains a given element); read this signature as saying that `elem`

only works on lists of things which can be compared to one another for equality. If you think about how you would write `elem`

yourself, that should make sense.

`Num a => ...`

means `a`

is a numeric type, meaning it supports some basic arithmetical operations: `+`

, `*`

, `-`

, `abs`

. I believe this is roughly similar to the mathematical notion of a ring. Basically all the types you think of as "number types" belong to this class: `Int`

, `Double`

, etc. You would see the `Num a =>`

constraint in front of a signature if the function was written to work generically with any kind of number. For example, `sum :: Num a => [a] -> a`

, which sums all the elements of a list of numbers, can work equally well on `[Int]`

, `[Double]`

, `[Rational]`

, etc... all it has to do is add up its contents, no matter what kind of numbers they are. But numbers they must be!

Basically, these type classes/constraints are an approach to "principled overloading" of functions. We can use `(==) :: Eq a => a -> a -> Bool`

on various types, but *not just any types*. Some things, for example functions, don't make sense to compare for equality (perhaps because equality isn't decidable for that type), and it *never* makes sense to compare two things of *different* types for equality (contrast this with Java, where you can compare any two objects of possibly different types for equality).

For further (very accessible) reading on type classes and constraints, I highly recommend Learn You a Haskell.