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|
(***********************************************************************)
(* ocamlbuild *)
(* *)
(* Nicolas Pouillard, Berke Durak, projet Gallium, INRIA Rocquencourt *)
(* *)
(* Copyright 2007 Institut National de Recherche en Informatique et *)
(* en Automatique. All rights reserved. This file is distributed *)
(* under the terms of the Q Public License version 1.0. *)
(* *)
(***********************************************************************)
(* Original author: Berke Durak *)
(* Glob *)
open My_std;;
open Bool;;
include Glob_ast;;
open Glob_lexer;;
let sf = Printf.sprintf;;
let brute_limit = 10;;
(*** string_of_token *)
let string_of_token = function
| ATOM _ -> "ATOM"
| AND -> "AND"
| OR -> "OR"
| NOT -> "NOT"
| LPAR -> "LPAR"
| RPAR -> "RPAR"
| TRUE -> "TRUE"
| FALSE -> "FALSE"
| EOF -> "EOF"
;;
(* ***)
(*** match_character_class *)
let match_character_class cl c =
Bool.eval
begin function (c1,c2) ->
c1 <= c && c <= c2
end
cl
;;
(* ***)
(*** NFA *)
module NFA =
struct
type transition =
| QCLASS of character_class
| QEPSILON
;;
module IS = Set.Make(struct type t = int let compare = compare let print = Format.pp_print_int end);;
module ISM = Map.Make(struct type t = IS.t let compare = IS.compare let print = IS.print end);;
type machine = {
mc_qi : IS.t;
mc_table : (character_class * IS.t) list array;
mc_qf : int;
mc_power_table : (char, IS.t ISM.t) Hashtbl.t
}
(*** build' *)
let build' p =
let count = ref 0 in
let transitions = ref [] in
let epsilons : (int * int) list ref = ref [] in
let state () = let id = !count in incr count; id in
let ( --> ) q1 t q2 =
match t with
| QEPSILON -> epsilons := (q1,q2) :: !epsilons; q1
| QCLASS cl -> transitions := (q1,cl,q2) :: !transitions; q1
in
(* Construit les transitions correspondant au motif donné et arrivant
* sur l'état qf. Retourne l'état d'origine. *)
let rec loop qf = function
| Epsilon -> qf
| Word u ->
let m = String.length u in
let q0 = state () in
let rec loop q i =
if i = m then
q0
else
begin
let q' =
if i = m - 1 then
qf
else
state ()
in
let _ = (q --> QCLASS(Atom(u.[i], u.[i]))) q' in
loop q' (i + 1)
end
in
loop q0 0
| Class cl ->
let q1 = state () in
(q1 --> QCLASS cl) qf
| Star p ->
(* The fucking Kleene star *)
let q2 = state () in
let q1 = loop q2 p in (* q1 -{p}-> q2 *)
let _ = (q1 --> QEPSILON) qf in
let _ = (q2 --> QEPSILON) q1 in
let _ = (q2 --> QEPSILON) q1 in
q1
| Concat(p1,p2) ->
let q12 = state () in
let q1 = loop q12 p1 in (* q1 -{p1}-> q12 *)
let q2 = loop qf p2 in (* q2 -{p2}-> qf *)
let _ = (q12 --> QEPSILON) q2 in
q1
| Union pl ->
let qi = state () in
List.iter
begin fun p ->
let q = loop qf p in (* q -{p2}-> qf *)
let _ = (qi --> QEPSILON) q in (* qi -{}---> q *)
()
end
pl;
qi
in
let qf = state () in
let qi = loop qf p in
let m = !count in
(* Compute epsilon closure *)
let graph = Array.make m IS.empty in
List.iter
begin fun (q,q') ->
graph.(q) <- IS.add q' graph.(q)
end
!epsilons;
let closure = Array.make m IS.empty in
let rec transitive past = function
| [] -> past
| q :: future ->
let past' = IS.add q past in
let future' =
IS.fold
begin fun q' future' ->
(* q -{}--> q' *)
if IS.mem q' past' then
future'
else
q' :: future'
end
graph.(q)
future
in
transitive past' future'
in
for i = 0 to m - 1 do
closure.(i) <- transitive IS.empty [i] (* O(n^2), I know *)
done;
(* Finally, build the table *)
let table = Array.make m [] in
List.iter
begin fun (q,t,q') ->
table.(q) <- (t, closure.(q')) :: table.(q)
end
!transitions;
(graph, closure,
{ mc_qi = closure.(qi);
mc_table = table;
mc_qf = qf;
mc_power_table = Hashtbl.create 37 })
;;
let build x = let (_,_, machine) = build' x in machine;;
(* ***)
(*** run *)
let run ?(trace=false) machine u =
let m = String.length u in
let apply qs c =
try
let t = Hashtbl.find machine.mc_power_table c in
ISM.find qs t
with
| Not_found ->
let qs' =
IS.fold
begin fun q qs' ->
List.fold_left
begin fun qs' (cl,qs'') ->
if match_character_class cl c then
IS.union qs' qs''
else
qs'
end
qs'
machine.mc_table.(q)
end
qs
IS.empty
in
let t =
try
Hashtbl.find machine.mc_power_table c
with
| Not_found -> ISM.empty
in
Hashtbl.replace machine.mc_power_table c (ISM.add qs qs' t);
qs'
in
let rec loop qs i =
if IS.is_empty qs then
false
else
begin
if i = m then
IS.mem machine.mc_qf qs
else
begin
let c = u.[i] in
if trace then
begin
Printf.printf "%d %C {" i c;
IS.iter (fun q -> Printf.printf " %d" q) qs;
Printf.printf " }\n%!"
end;
let qs' = apply qs c in
loop qs' (i + 1)
end
end
in
loop machine.mc_qi 0
;;
(* ***)
end
;;
(* ***)
(*** Brute *)
module Brute =
struct
exception Succeed;;
exception Fail;;
exception Too_hard;;
(*** match_pattern *)
let match_pattern counter p u =
let m = String.length u in
(** [loop i n p] returns [true] iff the word [u.(i .. i + n - 1)] is in the
** language generated by the pattern [p].
** We must have 0 <= i and i + n <= m *)
let rec loop (i,n,p) =
assert (0 <= i && 0 <= n && i + n <= m);
incr counter;
if !counter >= brute_limit then raise Too_hard;
match p with
| Word v ->
String.length v = n &&
begin
let rec check j = j = n or (v.[j] = u.[i + j] && check (j + 1))
in
check 0
end
| Epsilon -> n = 0
| Star(Class True) -> true
| Star(Class cl) ->
let rec check k =
if k = n then
true
else
(match_character_class cl u.[i + k]) && check (k + 1)
in
check 0
| Star _ -> raise Too_hard
| Class cl -> n = 1 && match_character_class cl u.[i]
| Concat(p1,p2) ->
let rec scan j =
j <= n && ((loop (i,j,p1) && loop (i+j, n - j,p2)) || scan (j + 1))
in
scan 0
| Union pl -> List.exists (fun p' -> loop (i,n,p')) pl
in
loop (0,m,p)
;;
(* ***)
end
;;
(* ***)
(*** fast_pattern_contents, fast_pattern, globber *)
type fast_pattern_contents =
| Brute of int ref * pattern
| Machine of NFA.machine
;;
type fast_pattern = fast_pattern_contents ref;;
type globber = fast_pattern atom Bool.boolean;;
(* ***)
(*** fast_pattern_of_pattern *)
let fast_pattern_of_pattern p = ref (Brute(ref 0, p));;
(* ***)
(*** add_dir *)
let add_dir dir x =
match dir with
| None -> x
| Some(dir) ->
match x with
| Constant(s) ->
Constant(My_std.filename_concat dir s)
| Pattern(p) ->
Pattern(Concat(Word(My_std.filename_concat dir ""), p))
;;
(* ***)
(*** add_ast_dir *)
let add_ast_dir dir x =
match dir with
| None -> x
| Some dir ->
let slash = Class(Atom('/','/')) in
let any = Class True in
let q = Union[Epsilon; Concat(slash, Star any)] in (* ( /** )? *)
And[Atom(Pattern(ref (Brute(ref 0, Concat(Word dir, q))))); x]
;;
(* ***)
(*** parse *)
let parse ?dir u =
let l = Lexing.from_string u in
let tok = ref None in
let f =
fun () ->
match !tok with
| None -> token l
| Some x ->
tok := None;
x
in
let g t =
match !tok with
| None -> tok := Some t
| Some t' ->
raise (Parse_error(sf "Trying to unput token %s while %s is active" (string_of_token t) (string_of_token t')))
in
let read x =
let y = f () in
if x = y then
()
else
raise (Parse_error(sf "Unexpected token, expecting %s, got %s" (string_of_token x) (string_of_token y)))
in
let rec atomizer continuation = match f () with
| NOT -> atomizer (fun x -> continuation (Not x))
| ATOM x ->
begin
let a =
match add_dir dir x with
| Constant u -> Constant u
| Pattern p -> Pattern(fast_pattern_of_pattern p)
in
continuation (Atom a)
end
| TRUE -> continuation True
| FALSE -> continuation False
| LPAR ->
let y = parse_s () in
read RPAR;
continuation y
| t -> raise (Parse_error(sf "Unexpected token %s in atomizer" (string_of_token t)))
and parse_s1 x = match f () with
| OR -> let y = parse_s () in Or[x; y]
| AND -> parse_t x
| t -> g t; x
and parse_t1 x y = match f () with
| OR -> let z = parse_s () in Or[And[x;y]; z]
| AND -> parse_t (And[x;y])
| t -> g t; And[x;y]
and parse_s () = atomizer parse_s1
and parse_t x = atomizer (parse_t1 x)
in
let x = parse_s () in
read EOF;
add_ast_dir dir x
;;
(* ***)
(*** eval *)
let eval g u =
Bool.eval
begin function
| Constant v -> u = v
| Pattern kind ->
match !kind with
| Brute(count, p) ->
begin
let do_nfa () =
let m = NFA.build p in
kind := Machine m;
NFA.run m u
in
if !count >= brute_limit then
do_nfa ()
else
try
Brute.match_pattern count p u
with
| Brute.Too_hard -> do_nfa ()
end
| Machine m -> NFA.run m u
end
g
(* ***)
(*** Debug *)
(*let (Atom(Pattern x)) = parse "<{a,b}>";;
#install_printer IS.print;;
#install_printer ISM.print;;
let (graph, closure, machine) = build' x;;*)
(* ***)
|
