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
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';])]