# Standard ML functor examples

Functors in Standard ML are related to the module system and can generate structures based on other structures. An example of a functor generating list combinators for various types of lists is given below, but this example has a problem:

The various types of lists all have advantages -- for example, lazy lists can be infinitely long, and concantenation lists have a O(1) concat operator. But when all of these list types conform to the same signature, the functor can only use their general properties.

My question is therefore: What is a good example of when functors are useful and the various generated structures don't lose their special abilities?

``````signature MYLIST =
sig
type 'a t
val null : 'a t -> bool
val empty : 'a t
val cons : 'a * 'a t -> 'a t
val hd : 'a t -> 'a
val tl : 'a t -> 'a t
end

structure RegularList : MYLIST =
struct
type 'a t = 'a list
val null = List.null
val empty = []
val cons = op::
val hd = List.hd
val tl = List.tl
end

structure LazyList : MYLIST =
struct
datatype 'a t = Nil | Cons of 'a * (unit -> 'a t)
val empty = Nil
fun null Nil = true
| null _ = false
fun cons (x, xs) = Cons (x, fn () => xs)
fun hd Nil = raise Empty
| hd (Cons (x, _)) = x
fun tl Nil = raise Empty
| tl (Cons (_, f)) = f ()
end

structure ConcatList : MYLIST =
struct
datatype 'a t = Nil | Singleton of 'a | Concat of 'a t * 'a t
val empty = Nil
fun null Nil = true
| null (Singleton _) = false
| null (Concat (xs, ys)) = null xs andalso null ys
fun cons (x, xs) = Concat (Singleton x, xs)
fun hd Nil = raise Empty
| hd (Singleton x) = x
| hd (Concat (xs, ys)) = hd xs
fun tl Nil = raise Empty
| tl (Singleton x) = Nil
| tl (Concat (xs, ys)) = (* exercise *)
end

signature MYLISTCOMB =
sig
type 'a t
val length : 'a liste -> int
val map : ('a -> 'b) -> 'a liste -> 'b liste
val foldl : ('a * 'b -> 'b) -> 'b -> 'a liste -> 'b
val append : 'a liste * 'a liste -> 'a liste
val concat : 'a liste liste -> 'a liste
val sort : ('a * 'a -> order) -> 'a t -> 'a t
end

functor ListComb (X : MYLIST) : MYLISTCOMB =
struct
type 'a t = 'a X.t
open X

fun length xs =
if null xs then 0
else 1 + length (tl xs)

fun map f xs =
if null xs then empty
else cons(f (hd xs), map f (tl xs))

fun foldl f e xs =
if null xs then e
else foldl f (f (hd xs, e)) (tl xs)

fun append (xs, ys) =
if null xs then ys
else cons (hd xs, append (tl xs, ys))

fun concat xs =
if null xs then empty
else append (hd xs, concat (tl xs))

fun sort cmp xs = (* exercise *)
end

structure RegularListComb = ListComb (RegularList)
structure LazyListComb = ListComb (LazyList)
structure ConcatListComb = ListComb (ConcatList)
``````
• I'm a little confused. The lack of visibility of implementation-specific functionality is kinda the point of functors in SML. Are you looking for some kind of guarantees of behaviour preservation? – Gian Oct 30 '12 at 22:52
• @Gian: He's looking for some good examples for demonstrating the usefulness of functors to students (in an introductory SML course). – Sebastian Paaske Tørholm Nov 1 '12 at 7:41
• In that case, have a look at CMlib: github.com/standardml/cmlib -- particularly things like 'streamable'. – Gian Nov 1 '12 at 11:39

Not sure I fully understand your question. Obviously, functors are useful for defining modular abstractions that (1) are polymorphic, (2) require a whole set of operations over their type parameters, and (3) provide types as part of their result (in particular, abstract types), and (4) provide an entire set of operations.

Note that your example doesn't make use of (3), which probably is the most interesting aspect of functors. Imagine, for example, implementing an abstract matrix type that you want to parameterise over the vector type it is based on.

One specific characteristic of ML functors -- as well as of core-language polymorphic functions -- is that they are parametric. Parametricity is a semantic property saying that evaluation (of polymorphic code) is oblivious to the concrete type(s) it is instantiated with. That is an important property, as it implies all kinds of semantic goodness. In particular, it provides very strong abstraction and reasoning principles (see e.g. Wadler's "Theorem's for free!", or the brief explanation I gave in reply to another question). It also is the basis for type-erasing compilation (i.e., no types are needed at runtime).

Parametricity implies that a single functor cannot have different implementations for different types -- which seems to be what you are asking about. But of course, you are free to write multiple functors that make different semantic/complexity assumptions about their parameters.

Here is a number of useful examples of SML functors. They are made on the following premise: If you can do one set of things, this enables you to do another set of things.

A functor for sets: If you can compare elements, you can create sets using balanced data structures (e.g. binary search trees or other kinds of trees).

``````signature SET =
sig
type elem
type set
val empty : set
val singleton : elem -> set
val union : set -> set -> set
val intersect : set -> set -> set
end

signature ORD =
sig
type t
val compare : t * t -> order
end

functor BalancedSetFunctor(structure Cmp : ORD) :> SET =
struct
type elem = Cmp.t
type set = ...

val empty = ...
fun singleton x = ...
fun union s1 s2 = ...
fun intersect s1 s2 = ...
end
``````

A functor for iteration: For any kind of collection of things (e.g. lists), if you can iterate them, you can automatically fold them. You can also create different structures for different ways to fold across the same datatype (e.g. pre-order, in-order and post-order traversal of trees).

``````signature ITERABLE =
sig
type elem
type collection
val next : collection -> (elem * collection) option
end

signature FOLD =
sig
type elem
type collection
val fold : (elem * 'b -> 'b) -> 'b -> collection -> 'b
end

functor FoldFunctor(Iter : ITERABLE) :> FOLD =
struct
type elem = Iter.elem
type collection = Iter.collection

fun fold f e xs =
case Iter.next xs of
NONE => e
| SOME (x, xs') => fold f (f (x, e)) xs'
end
``````

Functors are "lifters" - they lift (this verb is standard FP terminology): for a given set of types and values, they let you create a new set of types and values on top of them. All the modules conforming to the required module interface can "benefit" from the functor, but they don't lose their special abilities, if by abilities you mean the implementation specific advantages.

Your very example, for instance, works well to demonstrate my point: concatenation lists have a very fast `concat` operator, as you wrote, and when lifted with the functor, this 'ability' doesn't vanish. It's still there and perhaps even used by the functor code. So in this example the functor code actually benefit from the list implementation, without knowing it. That's a very powerful concept.

On the other hand, since modules have to fit an interface when lifted by a functor, the superfluous values and types are lost in the process, which can be annoying. Still, depending on the ML dialect, this restriction might be somewhat relaxed.

• â€śOn the other hand, since modules have to fit an interface when lifted by a functor, the superfluous values and types are lost in the processâ€ť: not necessarily, as the ascription to a signature may be transparent (unless I have not understood the point). By the way, please, do you know an onâ€‘line dictionary where other FP terms like â€śliftâ€ť are explained? – Hibou57 Feb 9 '14 at 17:57