As you describe, singleton types are those which have only one value (let's ignore
⊥ for the moment). Thus, the value of a singleton type has a unique type representing the value. The crux of dependent-type theory (DTT) is that types can depend on values (or, said another way, values can parameterise types). A type theory that allows types to depend on types can use singleton types to let types depend on singleton values. In contrast, type classes provide ad hoc polymorphism, where values can depend on types (the other way round to DTT where types depend on values).
A useful technique in Haskell is to define a class of related singleton types. The classic example is of natural numbers:
data S n = Succ n
data Z = Zero
class Nat n
instance Nat Z
instance Nat n => Nat (S n)
Provided further instances aren't added to
Nat class describes singleton types whose values/types are inductively defined natural numbers. Note that,
Zero is the only inhabitant of
Z but the type
S Int, for example, has many inhabitants (it is not a singleton); the
Nat class restricts the parameter of
S to singleton types. Intuitively, any data type with more than one data constructor is not a singleton type.
Give the above, we can write the dependently-typed successor function:
succ :: Nat n => n -> (S n)
succ n = Succ n
In the type signature, the type variable
n can be seen as a value since the
Nat n constraint restricts
n to the class of singleton types representing natural numbers. The return type of the
succ then depends on this value, where
S is parameterised by the value
Any value that can be inductively defined can be given a unique singleton type representation.
A useful technique is to use GADTs to parameterise non-singleton types with singleton types (i.e. with values). This can be used, for example, to give a type-level representation of the shape of an inductively defined data type. The classic example is a sized-list:
data List n a where
Nil :: List Z a
Cons :: Nat n => a -> List n a -> List (S n) a
Here the natural number singleton types parameterise the list-type by its length.
Thinking in terms of the polymorphic lambda calculus,
succ above takes two arguments, the type
n and then a value parameter of type
n. Thus, singleton types here provides a kind of Π-type, where
succ :: Πn:Nat . n -> S(n) where the argument to
succ in Haskell provides both the dependent product parameter
n:Nat (passed as the type parameter) and then the argument value.