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I'm implementing a packrat parser in OCaml, as per the Master Thesis by B. Ford. My parser should receive a data structure that represents the grammar of a language and parse given sequences of symbols.

I'm stuck with the memoization part. The original thesis uses Haskell's lazy evaluation to accomplish linear time complexity. I want to do this (memoization via laziness) in OCaml, but don't know how to do it.

So, how do you memoize functions by lazy evaluations in OCaml?

EDIT: I know what lazy evaluation is and how to exploit it in OCaml. The question is how to use it to memoize functions.

EDIT: The data structure I wrote that represents grammars is:

type ('a, 'b, 'c) expr =
| Empty of 'c
| Term of 'a * ('a -> 'c)
| NTerm of 'b
| Juxta of ('a, 'b, 'c) expr * ('a, 'b, 'c) expr * ('c -> 'c -> 'c)
| Alter of ('a, 'b, 'c) expr * ('a, 'b, 'c) expr
| Pred of ('a, 'b, 'c) expr * 'c
| NPred of ('a, 'b, 'c) expr * 'c
type ('a, 'b, 'c) grammar = ('a * ('a, 'b, 'c) expr) list

The (not-memoized) function that parse a list of symbols is:

let rec parse g v xs = parse' g (List.assoc v g) xs
and parse' g e xs =
  match e with
  | Empty y -> Parsed (y, xs)
  | Term (x, f) ->
     begin
       match xs with
       | x' :: xs when x = x' -> Parsed (f x, xs)
       | _ -> NoParse
     end
  | NTerm v' -> parse g v' xs
  | Juxta (e1, e2, f) ->
     begin
       match parse' g e1 xs with
       | Parsed (y, xs) ->
          begin
            match parse' g e2 xs with
            | Parsed (y', xs) -> Parsed (f y y', xs)
            | p -> p
          end
       | p -> p
     end
( and so on )

where the type of the return value of parse is defined by

type ('a, 'c) result = Parsed of 'c * ('a list) | NoParse

For example, the grammar of basic arithmetic expressions can be specified as g, in:

type nt = Add | Mult | Prim | Dec | Expr
let zero _  = 0
let g =
  [(Expr, Juxta (NTerm Add, Term ('$', zero), fun x _ -> x));
   (Add, Alter (Juxta (NTerm Mult, Juxta (Term ('+', zero), NTerm Add, fun _ x -> x), (+)), NTerm Mult));
   (Mult, Alter (Juxta (NTerm Prim, Juxta (Term ('*', zero), NTerm Mult, fun _ x -> x), ( * )), NTerm Prim));
   (Prim, Alter (Juxta (Term ('<', zero), Juxta (NTerm Dec, Term ('>', zero), fun x _ -> x), fun _ x -> x), NTerm Dec));
   (Dec, List.fold_left (fun acc d -> Alter (Term (d, (fun c -> int_of_char c - 48)), acc)) (Term ('0', zero)) ['1';'2';'3';])]
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I thought parckrat parsing is a well-known technique and so is its inventor's master's thesis. But it seems it isn't :-) –  Pteromys May 14 '12 at 10:43

3 Answers 3

The lazy keyword.

Here you can find some great examples.

If it fits your use case, you can also use OCaml streams instead of manually generating thunks.

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Why do you want to memoize functions? What you want to memoize is, I believe, the parsing result for a given (parsing) expression and a given position in the input stream. You could for instance use Ocaml's Hashtables for that.

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The idea of using lazyness for memoization is use not functions, but data structures, for memoization. Lazyness means that when you write let x = foo in some_expr, foo will not be evaluated immediately, but only as far as some_expr needs it, but that different occurences of xin some_expr will share the same trunk: as soon as one of them force computation, the result is available to all of them.

This does not work for functions: if you write let f x = foo in some_expr, and call f several times in some_expr, well, each call will be evaluated independently, there is not a shared thunk to store the results.

So you can get memoization by using a data structure instead of a function. Typically, this is done using an associative data structure: instead of computing a a -> b function, you compute a Table a b, where Table is some map from the arguments to the results. One example is this Haskell presentation of fibonacci:

fib n = fibTable !! n
fibTable = [0,1] ++ map (\n -> fib (n - 1) + fib (n - 2)) [2..]

(You can also write that with tail and zip, but this doesn't make the point clearer.)

See that you do not memoize a function, but a list: it is the list fibTable that does the memoization. You can write this in OCaml as well, for example using the LazyList module of the Batteries library:

open Batteries
module LL = LazyList

let from_2 = LL.seq 2 ((+) 1) (fun _ -> true)

let rec fib n = LL.at fib_table (n - 1) + LL.at fib_table (n - 2)
and fib_table = lazy (LL.Cons (0, LL.cons 1 <| LL.map fib from_2))

However, there is little interest in doing so: as you have seen in the example above, OCaml does not particularly favor call-by-need evaluation -- it's reasonable to use, but not terribly convenient as it was forced to be in Haskell. It is actually equally simple to directly write the cache structure by direct mutation:

open Batteries

let fib =
  let fib_table = DynArray.of_list [0; 1] in
  let get_fib n = DynArray.get fib_table n in
  fun n ->
    for i = DynArray.length fib_table to n do
      DynArray.add fib_table (get_fib (i - 1) + get_fib (i - 2))
    done;
    get_fib n

This example may be ill-chosen, because you need a dynamic structure to store the cache. In the packrat parser case, you're tabulating parsing on a known input text, so you can use plain arrays (indexed by the grammar rules): you would have an array of ('a, 'c) result option for each rule, of the size of the input length and initialized to None. Eg. juxta.(n) represents the result of trying the rule Juxta from input position n, or None if this has not yet been tried.

Lazyness is a nice way to present this kind of memoization, but is not always expressive enough: if you need, say, to partially free some part of your result cache to lower memory usage, you will have difficulties if you started from a lazy presentation. See this blog post for a remark on this.

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