It's actually just a normal data constructor that happens to be defined in the Prelude, which is the standard library that is imported automatically into every module.
What Maybe is, Structurally
The definition looks something like this:
data Maybe a = Just a
That declaration defines a type,
Maybe a, which is parameterized by a type variable
a, which just means that you can use it with any type in place of
Constructing and Destructing
The type has two constructors,
Just a and
Nothing. When a type has multiple constructors, it means that a value of the type must have been constructed with just one of the possible constructors. For this type, a value was either constructed via
Nothing, there are no other (non-error) possibilities.
Nothing has no parameter type, when it's used as a constructor it names a constant value that is a member of type
Maybe a for all types
a. But the
Just constructor does have a type parameter, which means that when used as a constructor it acts like a function from type
Maybe a, i.e. it has the type
a -> Maybe a
So, the constructors of a type build a value of that type; the other side of things is when you would like to use that value, and that is where pattern matching comes in to play. Unlike functions, constructors can be used in pattern binding expressions, and this is the way in which you can do case analysis of values that belong to types with more than one constructor.
In order to use a
Maybe a value in a pattern match, you need to provide a pattern for each constructor, like so:
case maybeVal of
Nothing -> "There is nothing!"
Just val -> "There is a value, and it is " ++ (show val)
In that case expression, the first pattern would match if the value was
Nothing, and the second would match if the value was constructed with
Just. If the second one matches, it also binds the name
val to the parameter that was passed to the
Just constructor when the value you're matching against was constructed.
What Maybe Means
Maybe you were already familiar with how this worked; there's not really any magic to
Maybe values, it's just a normal Haskell Algebraic Data Type (ADT). But it's used quite a bit because it effectively "lifts" or extends a type, such as
Integer from your example, into a new context in which it has an extra value (
Nothing) that represents a lack of value! The type system then requires that you check for that extra value before it will let you get at the
Integer that might be there. This prevents a remarkable number of bugs.
Many languages today handle this sort of "no-value" value via NULL references. Tony Hoare, an eminent computer scientist (he invented Quicksort and is a Turing Award winner), owns up to this as his "billion dollar mistake". The Maybe type is not the only way to fix this, but it has proven to be an effective way to do it.
Maybe as a Functor
The idea of transforming one type to another one such that operations on the old type can also be transformed to work on the new type is the concept behind the Haskell type class called
Maybe a has a useful instance of.
Functor provides a method called
fmap, which maps functions that range over values from the base type (such as
Integer) to functions that range over values from the lifted type (such as
Maybe Integer). A function transformed with
fmap to work on a
Maybe value works like this:
case maybeVal of
Nothing -> Nothing -- there is nothing, so just return Nothing
Just val -> Just (f val) -- there is a value, so apply the function to it
So if you have a
Maybe Integer value
m_x and an
Int -> Int function
f, you can do
fmap f m_x to apply the function
f directly to the
Maybe Integer without worrying if it's actually got a value or not. In fact, you could apply a whole chain of lifted
Integer -> Integer functions to
Maybe Integer values and only have to worry about explicitly checking for
Nothing once when you're finished.
Maybe as a Monad
I'm not sure how familiar you are with the concept of a
Monad yet, but you have at least used
IO a before, and the type signature
IO a looks remarkably similar to
Maybe a. Although
IO is special in that it doesn't expose its constructors to you and can thus only be "run" by the Haskell runtime system, it's still also a
Functor in addition to being a
Monad. In fact, there's an important sense in which a
Monad is just a special kind of
Functor with some extra features, but this isn't the place to get into that.
Anyway, Monads like
IO map types to new types that represent "computations that result in values" and you can lift functions into
Monad types via a very
fmap-like function called
liftM that turns a regular function into a "computation that results in the value obtained by evaluating the function."
You have probably guessed (if you have read this far) that
Maybe is also a
Monad. It represents "computations that could fail to return a value". Just like with the
fmap example, this lets you do a whole bunch of computations without having to explicitly check for errors after each step. And in fact, the way the
Monad instance is constructed, a computation on
Maybe values stops as soon as a
Nothing is encountered, so it's kind of like an immediate abort or a valueless return in the middle of a computation.
You Could Have Written Maybe
Like I said before, there is nothing inherent to the
Maybe type that is baked into the language syntax or runtime system. If Haskell didn't provide it by default, you could provide all of its functionality yourself! In fact, you could write it again yourself anyway, with different names, and get the same functionality.
Hopefully you understand the
Maybe type and its constructors now, but if there is still anything unclear, let me know!