# Doing a N-dimensional walk in pure functional ML?

The idea is to walk over multiple dimensions, each one defined as a range

``````(* lower_bound, upper_bound, number_of_steps *)
type range = real * real * int
``````

so functions like `fun foo y x` or `fun foo z y x` could be applied to the whole square X*Y or cube X*Y*Z.

SML/NJ doesn't like my implementation below :

``````test2.sml:7.5-22.6 Error: right-hand-side of clause doesn't agree with function result type [circularity]
expression:  (real -> 'Z) -> unit
result type:  'Z -> 'Y
in declaration:
walk = (fn arg => (fn <pat> => <exp>))
``````

Here's the code :

``````fun walk []      _ = ()
| walk (r::rs) f =
let
val (k0, k1, n) = r
val delta = k1 - k0
val step = delta / real n

fun loop 0 _ = ()
| loop i k =
let in
walk rs (f k) ;          (* Note (f k) "eats" the first argument.
I guess SML doesn't like having the
type of walk change in the middle of its
definition *)
loop (i - 1) (k + step)
end
in
loop n k0
end

fun do2D y x = (* ... *) ()
fun do3D z y x = (* ... *) ()

val x_axis = (0.0, 1.0, 10)
val y_axis = (0.0, 1.0, 10)
val z_axis = (0.0, 1.0, 10)

val _ = walk [y_axis, x_axis] do2D
val _ = walk [z_axis, y_axis, x_axis] do3D
``````

Is this kind of construct even possible ?

Any pointer welcomed.

-
By the way, I disagree with your use of "pure functional": this is only useful in an imperative language like SML. `unit ; unit` sequencing is meaningless without side-effects. –  ephemient Jun 26 '09 at 17:13
That's what I expected, but that's not "pure" at all. Oh well -- at least SML has a guaranteed order of evaluation, unlike some other functional languages which are truly pure. –  ephemient Jun 26 '09 at 17:43
True but the function do2D and do3D are simple print statements so I stripped as much code as possible for testing –  diapir Jun 26 '09 at 17:48

Is `walk` expressible in ML's type system?

``````val walk : range list -> (real -> real -> unit) -> unit
val walk : range list -> (real -> real -> real -> unit) -> unit
``````

The same one value cannot possibly exist with both those types in ML.

We can easily generate values for each of the desired types, though.

``````type range = real * real * int

signature WALK =
sig
type apply
val walk : range list -> apply -> unit
end

structure Walk0 : WALK =
struct
type apply = unit
fun walk _ _ = ()
end

functor WALKF (Walk : WALK) : WALK =
struct
type apply = real -> Walk.apply
fun walk ((low, high, steps)::rs) f =
let fun loop i =
if i > steps then () else
let val x = low + (high - low) * real i / real steps
in (Walk.walk rs (f x); loop (i + 1)) end
in loop 0 end
end

struture Walk1 = WALKF(Walk0)
struture Walk2 = WALKF(Walk1)
struture Walk3 = WALKF(Walk2)
``````

With this, the following values exist with the desired types.

``````val Walk0.walk : range list -> unit -> unit
val Walk1.walk : range list -> (real -> unit) -> unit
val Walk2.walk : range list -> (real -> real -> unit) -> unit
val Walk3.walk : range list -> (real -> real -> real -> unit) -> unit
``````

Then you only need to write

``````val _ = Walk2.walk [y_axis, x_axis] do2D
val _ = Walk3.walk [z_axis, y_axis, x_axis] do3D
``````

To use the same `walk` for every dimensionality, you need it to use the same type for every dimensionality.

``````fun walk nil f = f nil
| walk ((low, high, steps)::rs) f =
let fun loop i =
if i > steps then () else
let val x = low + (high - low) * real i / real steps
in (walk rs (fn xs -> f (x::xs)); loop (i + 1)) end
in loop 0 end
``````

Because the type is changed to

``````val walk : range list -> (real list -> unit) -> unit
``````

your usage also has to change to

``````fun do2D [y,x] = (* ... *) ()
fun do3D [z,y,x] = (* ... *) ()
``````
-
Wow, thanks a lot. I still need to get my head around functors (who would have guessed ...) Would you consider your first solution an abusive hack or some legit code ? Also, thanks for pointing out discrepancies in my style. Cheers. –  diapir Jun 26 '09 at 18:07
I don't consider the first solution a hack. In fact, the first solution ensures that `f` always takes the correct number of arguments, while the second doesn't. Neither ensures that the list of ranges has the correct length, though, so I don't like this structure in general. –  ephemient Jun 26 '09 at 18:40
``````fun walk lst f = let
fun aux rev_prefix [] = f (rev rev_prefix)
| aux rev_prefix (r::rs) = let
val (k0, k1, n) = r
val delta = k1 - k0
val step = delta / real n

fun loop 0 _ = ()
| loop i k = (
aux (k+step :: rev_prefix) rs;
loop (i - 1) (k + step)
)
in
loop n k0
end
in
aux [] lst
end

fun do2D [x,y] = print (Real.toString x ^ "\t" ^
Real.toString y ^ "\n")
fun do3D [x,y,z] = print (Real.toString x ^ "\t" ^
Real.toString y ^ "\t" ^
Real.toString z ^ "\n")

val x_axis = (0.0, 1.0, 10)
val y_axis = (0.0, 1.0, 10)
val z_axis = (0.0, 1.0, 10)

val () = walk [y_axis, x_axis] do2D
val () = walk [z_axis, y_axis, x_axis] do3D
``````
-
Looks equivalent to my second solution? (With a `fun walk2 l f = walk l (f o rev)` wrapper.) –  ephemient Jun 26 '09 at 18:52

Found this implementation for variable number of arguments. Not sure it applies but it looks quite ugly.

-
Oh wow, that \$ hack is unbelievable... yeah, that's roughly equivalent to the "variable arguments" workaround in Haskell too, but with a lot of additional pain because of the lack of typeclasses and dependent types. –  ephemient Jun 26 '09 at 18:38