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I was pleasantly surprised to discover that OCaml has been supporting modules as first-class objects since v3.12 (2011). Intuition suggests that first-class modules should be expressive enough to simulate Haskell-style typeclasses in OCaml. Turns out this is the route taken by Leo White et al to introduce adhoc polymorphism via Modular Implicits to OCaml. White et al’s paper describes their principled approach in detail, and is definitely worth a read. In this blog, I present a series of OCaml examples involving (first-class) modules that gradually build up to modular implicits. The full code (with directions to run) is available here.

First lets recall the basics of modules and module types (signatures) in OCaml. Lets define a module type T1 :

module type T1 = sig type a val to_string : a -> string val eg : a end

Lets also define a couple of modules of type T1 :

module IntT1 : ( T1 with type a = int ) = struct type a = int let to_string = string_of_int let eg = 0 end (* module IntT1 : sig type a = int val to_string : a -> string end *) module BoolT1 : ( T1 with type a = bool ) = struct type a = bool let to_string = string_of_bool let eg = false end

Below is a functor that creates a module of type T1 .

module XT1 ( X : sig type t val to_string : t -> string val eg : t end ) : ( T1 with type a = X . t ) = struct type a = X . t let to_string = X . to_string let eg = X . eg end

The type of XT1 is:

module XT1 : functor ( X : sig type t val to_string : t -> string end ) -> sig type a = X . t val to_string : a -> string end

OCaml has first class modules. A first-class module is created by “packing” a module with a signature. Done using the “module” keyword.

let i = ( module IntT1 : T1 ) let b = ( module BoolT1 : T1 )

It is possible to create a list of first-class modules, each encapsulating a different type:

let mod_list = [ i ; b ]

However, i and b cannot be used as modules themselves; they need to be unpacked first. Unpacking is done using the “val” keyword:

module I = ( val i : T1 ) module B = ( val b : T1 )

Note that the information that type a in I is int is lost while packing it into a module of type T1 . Thus I.eg is an abstract value of type I.a , as confirmed by utop:

utop # I . eg ;; - : I . a = < abstr >

Likewise, B.eg is an <abstr> value of type B.a .

Alternatively, we could’ve packed IntT1 into a module of type (T1 with type a = int) , but that makes it impossible to create [i;b] .

It would have been clear by now that first-class modules are simply variables with existential types. We pack a module to introduce an existential type, and unpack it to eliminate the existential. Like the values of other types, values of existential types are first class. The t2_of_t1 function shown below takes a value of type module T1 , which is an existential type, and returns a value of type module T2 , which is another existential type:

module type T2 = sig include T1 val print : a -> unit end (** val t2_of_t1: (module T1) -> (module T2) *) let t2_of_t1 ( x : ( module T1 )) = let module X = ( val x : T1 ) in let module Y = struct include X let print a = print_string @@ to_string a ;; end in let y = ( module Y : T2 ) in y

Unpacking an existential (i.e., conversion from a first-class module to a normal module) is done automatically by OCaml during pattern matches, so t2_of_t1 can be simplified as following:

let t2_of_t1 ( module X : T1 ) = let module Y = struct include X let print a = print_string @@ to_string a ;; end in let y = ( module Y : T2 ) in y

We can now construct modules at run-time:

module I2 = ( val ( t2_of_t1 i ) : T2 )

This feature lets us choose between various implementations of a signature at run-time, depending on the execution parameters. Another big advantage of first-class modules is that it helps us achieve qualified/bounded/adhoc polymorphism, and lets us obtain Haskell-style typeclasses in ML. For instance, lets consider a SERIALIZABLE signature that characterizes all serializable types:

module type SERIALIZABLE = sig type t val to_string : t -> string val of_string : string -> t end (* For convenience *) exception ConversionError

Abstract type t is supposed to be instantiated with any concrete serializable type. Base types such as int, float etc., are obviously serializable:

module SInt : SERIALIZABLE with type t = int = struct type t = int let to_string = string_of_int let of_string = int_of_string end module SFloat : SERIALIZABLE with type t = float = struct type t = float let to_string = string_of_float let of_string = float_of_string end

Polymorphic types like lists are serializable iff their type parameters are serializable:

module SList ( A : SERIALIZABLE ) : ( SERIALIZABLE with type t = A . t list ) = struct type t = A . t list let to_string l = "[" ^ ( String . concat ";" @@ List . map A . to_string l ) ^ "]" let of_string s = let l = String . length s in let _ = if l >= 2 && s . [ 0 ] = ' [ ' && s . [ l - 1 ] = ' ] ' then () else raise ConversionError in let mid = String . sub s 1 ( l - 2 ) in let tokens = Str . split ( Str . regexp ";" ) mid in let join p s = match p with "" -> s | _ -> p ^ ";" ^ s in let els = List . rev @@ fst @@ List . fold_left ( fun ( els , p ) s -> try let el = A . of_string @@ join p s in ( el :: els , "" ) with ConversionError -> ( els , join p s )) ([] , "" ) tokens in els end

An aside: we implemented a serializable list as a functor above. An alternative approach is to implement it as a function. The second approach is more general than the first because functions can have polymorphic types but functors cannot (in OCaml).

(* * val mk_SList : * (module SERIALIZABLE with type t = 'a) -> * (module SERIALIZABLE with type t = 'a list) *) let mk_SList ( type a ) ( module A : SERIALIZABLE with type t = a ) = let module SList = struct module S = SList ( A ) include S end in ( module SList : SERIALIZABLE with type t = a list )

We now have multiple to_string and of_string functions from SInt, SFloat, SList, and their compositions. Using first-class modules, we can write to_string and of_string wrappers for these functions that accept module parameters:

let to_string ( type a ) ( module S : SERIALIZABLE with type t = a ) = S . to_string let of_string ( type a ) ( module S : SERIALIZABLE with type t = a ) = S . of_string let "2" = to_string ( module SInt ) 2 let 3 = of_string ( module SInt ) "3" let "[2;3]" = to_string ( module SList ( SInt )) [ 2 ; 3 ];; let [ 2 ; 3 ] = of_string ( module SList ( SInt )) "[2;3]" ;; let "[[2;3];[4;5]]" = to_string ( module SList ( SList ( SInt ))) [[ 2 ; 3 ];[ 4 ; 5 ]];; let [[ 2 ; 3 ];[ 4 ; 5 ]] = of_string ( module SList ( SList ( SInt ))) "[[2;3];[4;5]]" ;;

Observe that in the above examples, single to_string / of_string function is being used for various SERIALIZABLE types. This is exactly the behavior that typeclasses offer in Haskell! There is, however, one significant difference. While GHC infers typeclasses automatically, here we have to explicitly pass the module parameters to to_string / of_string functions. This seems redundant, given that such module parameters can be inferred from the context. For example, when the to_string function is applied on [[2;3];[4;5]] , the only module parameter that lets this expression typecheck is SList(SList(SInt)) , which must be inferable. This is infact the sort of reasoning performed by Modular Implicits (Leo White et al) OCaml extension, which lets us mark module parameters to a function as implicit, and later elide them when applying the function. This is demonstrated below:

We first mark the modules that serve as typeclass instances with the keyword implicit :

implicit module SInt : SERIALIZABLE with type t = int = struct type t = int let to_string = string_of_int let of_string = int_of_string end implicit module SFloat : SERIALIZABLE with type t = float = struct type t = float let to_string = string_of_float let of_string = float_of_string end

Functors can also be marked implicit, as long as their arguments are implicit (marked via the curly braces).

implicit module SList { A : SERIALIZABLE } : ( SERIALIZABLE with type t = A . t list ) = struct type t = A . t list let to_string l = "[" ^ ( String . concat ";" @@ List . map A . to_string l ) ^ "]" let of_string s = let l = String . length s in let _ = if l >= 2 && s . [ 0 ] = ' [ ' && s . [ l - 1 ] = ' ] ' then () else raise ConversionError in let mid = String . sub s 1 ( l - 2 ) in let tokens = Str . split ( Str . regexp ";" ) mid in let join p s = match p with "" -> s | _ -> p ^ ";" ^ s in let els = List . rev @@ fst @@ List . fold_left ( fun ( els , p ) s -> try let el = A . of_string @@ join p s in ( el :: els , "" ) with ConversionError -> ( els , join p s )) ([] , "" ) tokens in els end

Lastly, we mark the module parameters of functions (for which adhoc polymorphism is intended) as implicit (again using curly braces):

let to_string ( type a ) { S : SERIALIZABLE with type t = a } = S . to_string let of_string ( type a ) { S : SERIALIZABLE with type t = a } = S . of_string

Module parameters can now be elided:

let "2" = to_string 2 let 3 = of_string "3" let "[2;3]" = to_string [ 2 ; 3 ];; let [ 2 ; 3 ] = of_string "[2;3]" ;; let "[[2;3];[4;5]]" = to_string [[ 2 ; 3 ];[ 4 ; 5 ]];; let [[ 2 ; 3 ];[ 4 ; 5 ]] = of_string "[[2;3];[4;5]]" ;;

Observe that to_string and of_string do not take module parameters. The code behaves as if both the functions are part of a typeclass, for which int, float and list instances exist.

So, to conclude, First-class modules + implicits = typeclasses in ML!.