In Haskell, overloading is done using type classes. This is quite different from overloading in C#, as type classes are more similar to interfaces in C#, although they are also more powerful*.
For example, to have a function which will be able to accept either an
Integer or a
Bool, you can write something like this:
class Foo a where
foo :: a -> String
instance Foo Integer where
foo n = show (n+42)
instance Foo Bool where
foo b = if b then "Hello" else "Goodbye"
Testing this out in the interpreter, we see that the function
foo has a type with constraints.
*Main> :t foo
foo :: Foo a => a -> String
This means that the function will work for types
a for which we have defined a
*Main> foo 1295
*Main> foo False
If we attempt to use it on a type for which there is no such instance, we get an error.
*Main> foo "Hello"
No instance for (Foo [Char])
arising from a use of `foo'
Possible fix: add an instance declaration for (Foo [Char])
In the expression: foo "Hello"
In an equation for `it': it = foo "Hello"
For your example, I don't think it's very useful to overload this function in such a way in Haskell. In fact, the
lcm function in the standard library is already overloaded.
*Main> :t lcm
lcm :: Integral a => a -> a -> a
This means that it will work on any type for which there is an
Integral instance. In this case, that's all integer-like types, including the machine-sized
Int, the arbitrary-size
Integer, and others such as
Int64 and so on.
The list version can be written as
foldl1' lcm, so there might not be much of a need to provide such an overload in the first place.
* For one thing, type class instances are passed separately from the objects they apply to. This makes things like multiple dispatch a lot cleaner. This also means you can overload on the return type of a function, which would be impossible in C#. Type classes can also be used with type constructors;
Monad is perhaps the most famous example of such a type class.