The MLton structure contains a lot of functionality that is not available in the Basis Library. As a warning, please keep in mind that the MLton structure and its substructures do change from release to release of MLton.

structure MLton:
   sig
      val eq: 'a * 'a -> bool
      val equal: 'a * 'a -> bool
      val hash: 'a -> Word32.word
      val isMLton: bool
      val share: 'a -> unit
      val shareAll: unit -> unit
      val size: 'a -> int

      structure Array: MLTON_ARRAY
      structure BinIO: MLTON_BIN_IO
      structure CharArray: MLTON_MONO_ARRAY where type t = CharArray.array
                                            where type elem = CharArray.elem
      structure CharVector: MLTON_MONO_VECTOR where type t = CharVector.vector
                                              where type elem = CharVector.elem
      structure Cont: MLTON_CONT
      structure Exn: MLTON_EXN
      structure Finalizable: MLTON_FINALIZABLE
      structure GC: MLTON_GC
      structure IntInf: MLTON_INT_INF
      structure Itimer: MLTON_ITIMER
      structure LargeReal: MLTON_REAL where type t = LargeReal.real
      structure LargeWord: MLTON_WORD where type t = LargeWord.word
      structure Platform: MLTON_PLATFORM
      structure Pointer: MLTON_POINTER
      structure ProcEnv: MLTON_PROC_ENV
      structure Process: MLTON_PROCESS
      structure Profile: MLTON_PROFILE
      structure Random: MLTON_RANDOM
      structure Real: MLTON_REAL where type t = Real.real
      structure Real32: sig
                           include MLTON_REAL
                           val castFromWord: Word32.word -> t
                           val castToWord: t -> Word32.word
                        end where type t = Real32.real
      structure Real64: sig
                           include MLTON_REAL
                           val castFromWord: Word64.word -> t
                           val castToWord: t -> Word64.word
                        end where type t = Real64.real
      structure Rlimit: MLTON_RLIMIT
      structure Rusage: MLTON_RUSAGE
      structure Signal: MLTON_SIGNAL
      structure Syslog: MLTON_SYSLOG
      structure TextIO: MLTON_TEXT_IO
      structure Thread: MLTON_THREAD
      structure Vector: MLTON_VECTOR
      structure Weak: MLTON_WEAK
      structure Word: MLTON_WORD where type t = Word.word
      structure Word8: MLTON_WORD where type t = Word8.word
      structure Word16: MLTON_WORD where type t = Word16.word
      structure Word32: MLTON_WORD where type t = Word32.word
      structure Word64: MLTON_WORD where type t = Word64.word
      structure Word8Array: MLTON_MONO_ARRAY where type t = Word8Array.array
                                             where type elem = Word8Array.elem
      structure Word8Vector: MLTON_MONO_VECTOR where type t = Word8Vector.vector
                                               where type elem = Word8Vector.elem
      structure World: MLTON_WORLD
   end

Substructures

Values

  • eq (x, y)

    returns true if x and y are equal as pointers. For simple types like char, int, and word, this is the same as equals. For arrays, datatypes, strings, tuples, and vectors, this is a simple pointer equality. The semantics is a bit murky.

  • equal (x, y)

    returns true if x and y are structurally equal. For equality types, this is the same as PolymorphicEquality. For other types, it is a conservative approximation of equivalence.

  • hash x

    returns a structural hash of x. The hash function is consistent between execution of the same program, but may not be consistent between different programs.

  • isMLton

    is always true in a MLton implementation, and is always false in a stub implementation.

  • share x

    maximizes sharing in the heap for the object graph reachable from x.

  • shareAll ()

    maximizes sharing in the heap by sharing space for equivalent immutable objects. A call to shareAll performs a major garbage collection, and takes time proportional to the size of the heap.

  • size x

    returns the amount of heap space (in bytes) taken by the value of x, including all objects reachable from x by following pointers. It takes time proportional to the size of x. See below for an example.

Example of MLton.size

This example, size.sml, demonstrates the application of MLton.size to many different kinds of objects.

fun 'a printSize (name: string, value: 'a): unit=
   (print "The size of "
    ; print name
    ; print " is "
    ; print (Int.toString (MLton.size value))
    ; print " bytes.\n")

val l = [1, 2, 3, 4]

val _ =
   (
    printSize ("an int list of length 4", l)
    ; printSize ("a string of length 10", "0123456789")
    ; printSize ("an int array of length 10", Array.tabulate (10, fn _ => 0))
    ; printSize ("a double array of length 10",
                 Array.tabulate (10, fn _ => 0.0))
    ; printSize ("an array of length 10 of 2-ples of ints",
                 Array.tabulate (10, fn i => (i, i + 1)))
    ; printSize ("a useless function", fn _ => 13)
    )

(* This is here so that the list is "useful".
 * If it were removed, then the optimizer (remove-unused-constructors)
 * would remove l entirely.
 *)
val _ = if 10 = foldl (op +) 0 l
           then ()
        else raise Fail "bug"

local
   open MLton.Cont
in
   val rc: int option t option ref = ref NONE
   val _ =
      case callcc (fn k: int option t => (rc := SOME k; throw (k, NONE))) of
         NONE => ()
       | SOME i => print (concat [Int.toString i, "\n"])
end

val _ = printSize ("a continuation option ref", rc)

val _ =
   case !rc of
      NONE => ()
    | SOME k => (rc := NONE; MLton.Cont.throw (k, SOME 13))

Compile and run as usual.

% mlton size.sml
% ./size
The size of an int list of length 4 is 48 bytes.
The size of a string of length 10 is 24 bytes.
The size of an int array of length 10 is 52 bytes.
The size of a double array of length 10 is 92 bytes.
The size of an array of length 10 of 2-ples of ints is 92 bytes.
The size of a useless function is 0 bytes.
The size of a continuation option ref is 4544 bytes.
13
The size of a continuation option ref is 8 bytes.

Note that sizes are dependent upon the target platform and compiler optimizations.