X-Git-Url: http://git.nguyen.vg/gitweb/?p=tatoo.git;a=blobdiff_plain;f=src%2Fata.ml;h=3263e466eec10f5a67fc6d4b9ca04cd5ae51bea5;hp=7310839afc3960fa99cd8c68fc10779179b69f02;hb=c36250a4de897883d0080fc369d784abf0e2ebe8;hpb=af9d790ca62e678e8e70ab8d8fa7f804985a75e0 diff --git a/src/ata.ml b/src/ata.ml index 7310839..3263e46 100644 --- a/src/ata.ml +++ b/src/ata.ml @@ -22,6 +22,57 @@ type move = [ `First_child | `Previous_sibling | `Stay ] +module Move = + struct + type t = move + type 'a table = 'a array + let idx = function + | `First_child -> 0 + | `Next_sibling -> 1 + | `Parent -> 2 + | `Previous_sibling -> 3 + | `Stay -> 4 + let ridx = function + | 0 -> `First_child + | 1 -> `Next_sibling + | 2 -> `Parent + | 3 -> `Previous_sibling + | 4 -> `Stay + | _ -> assert false + + let create_table a = Array.make 5 a + let get m k = m.(idx k) + let set m k v = m.(idx k) <- v + let iter f m = Array.iteri (fun i v -> f (ridx i) v) m + let fold f m acc = + let acc = ref acc in + iter (fun i v -> acc := f i v !acc) m; + !acc + let for_all p m = + try + iter (fun i v -> if not (p i v) then raise Exit) m; + true + with + Exit -> false + let exists p m = + try + iter (fun i v -> if p i v then raise Exit) m; + false + with + Exit -> true + let print ppf m = + match m with + `First_child -> fprintf ppf "%s" Pretty.down_arrow + | `Next_sibling -> fprintf ppf "%s" Pretty.right_arrow + | `Parent -> fprintf ppf "%s" Pretty.up_arrow + | `Previous_sibling -> fprintf ppf "%s" Pretty.left_arrow + | `Stay -> fprintf ppf "%s" Pretty.bullet + + let print_table pr_e ppf m = + iter (fun i v -> fprintf ppf "%a: %a" print i pr_e v; + if (idx i) < 4 then fprintf ppf ", ") m + end + type predicate = Move of move * State.t | Is_first_child | Is_next_sibling @@ -43,15 +94,8 @@ struct let print ppf a = match a.node with - | Move (m, q) -> begin - match m with - `First_child -> fprintf ppf "%s" Pretty.down_arrow - | `Next_sibling -> fprintf ppf "%s" Pretty.right_arrow - | `Parent -> fprintf ppf "%s" Pretty.up_arrow - | `Previous_sibling -> fprintf ppf "%s" Pretty.left_arrow - | `Stay -> fprintf ppf "%s" Pretty.bullet - end; - fprintf ppf "%a" State.print q + | Move (m, q) -> + fprintf ppf "%a%a" Move.print m State.print q | Is_first_child -> fprintf ppf "%s?" Pretty.up_arrow | Is_next_sibling -> fprintf ppf "%s?" Pretty.left_arrow | Is k -> fprintf ppf "is-%a?" Tree.NodeKind.print k @@ -107,22 +151,39 @@ struct let stay q = mk_move `Stay q - let get_states phi = - fold (fun phi acc -> + let get_states_by_move phi = + let table = Move.create_table StateSet.empty in + iter (fun phi -> match expr phi with - | Boolean.Atom ({ Atom.node = Move(_,q) ; _ }, _) -> StateSet.add q acc - | _ -> acc - ) phi StateSet.empty + | Boolean.Atom ({ Atom.node = Move(v,q) ; _ }, _) -> + let s = Move.get table v in + Move.set table v (StateSet.add q s) + | _ -> () + ) phi; + table + let get_states phi = + let table = get_states_by_move phi in + Move.fold (fun _ s acc -> StateSet.union s acc) table StateSet.empty end -module Transition = Hcons.Make (struct +module Transition = + struct + include Hcons.Make (struct type t = State.t * QNameSet.t * Formula.t let equal (a, b, c) (d, e, f) = a == d && b == e && c == f let hash (a, b, c) = HASHINT4 (PRIME1, a, ((QNameSet.uid b) :> int), ((Formula.uid c) :> int)) end) + let print ppf t = + let q, l, f = t.node in + fprintf ppf "%a, %a %s %a" + State.print q + QNameSet.print l + Pretty.double_right_arrow + Formula.print f + end module TransList : sig @@ -142,27 +203,17 @@ end = type t = { id : Uid.t; mutable states : StateSet.t; + mutable starting_states : StateSet.t; mutable selecting_states: StateSet.t; transitions: (State.t, (QNameSet.t*Formula.t) list) Hashtbl.t; } - +let uid t = t.id let get_states a = a.states +let get_starting_states a = a.starting_states let get_selecting_states a = a.selecting_states -let get_trans a tag states = - StateSet.fold (fun q acc0 -> - try - let trs = Hashtbl.find a.transitions q in - List.fold_left (fun acc1 (labs, phi) -> - if QNameSet.mem tag labs then - TransList.cons (Transition.make (q, labs, phi)) acc1 - else acc1) acc0 trs - with Not_found -> acc0 - ) states TransList.nil - - let _pr_buff = Buffer.create 50 let _str_fmt = formatter_of_buffer _pr_buff @@ -171,13 +222,18 @@ let _flush_str_fmt () = pp_print_flush _str_fmt (); Buffer.clear _pr_buff; s let print fmt a = + let _ = _flush_str_fmt() in fprintf fmt "Internal UID: %i@\n\ States: %a@\n\ + Number of states: %i@\n\ + Starting states: %a@\n\ Selection states: %a@\n\ Alternating transitions:@\n" (a.id :> int) StateSet.print a.states + (StateSet.cardinal a.states) + StateSet.print a.starting_states StateSet.print a.selecting_states; let trs = Hashtbl.fold @@ -211,6 +267,28 @@ let print fmt a = ) strs_strings; fprintf fmt "%s@\n" line + +let get_trans a tag states = + StateSet.fold (fun q acc0 -> + try + let trs = Hashtbl.find a.transitions q in + List.fold_left (fun acc1 (labs, phi) -> + if QNameSet.mem tag labs then + TransList.cons (Transition.make (q, labs, phi)) acc1 + else acc1) acc0 trs + with Not_found -> acc0 + ) states TransList.nil + + +let get_form a tag q = + try + let trs = Hashtbl.find a.transitions q in + List.fold_left (fun aphi (labs, phi) -> + if QNameSet.mem tag labs then Formula.or_ aphi phi else aphi + ) Formula.false_ trs + with + Not_found -> Formula.false_ + (* [complete transitions a] ensures that for each state q and each symbols s in the alphabet, a transition q, s exists. @@ -219,19 +297,24 @@ let print fmt a = let complete_transitions a = StateSet.iter (fun q -> - let qtrans = Hashtbl.find a.transitions q in - let rem = - List.fold_left (fun rem (labels, _) -> - QNameSet.diff rem labels) QNameSet.any qtrans - in - let nqtrans = - if QNameSet.is_empty rem then qtrans - else - (rem, Formula.false_) :: qtrans - in - Hashtbl.replace a.transitions q nqtrans + if StateSet.mem q a.starting_states then () + else + let qtrans = Hashtbl.find a.transitions q in + let rem = + List.fold_left (fun rem (labels, _) -> + QNameSet.diff rem labels) QNameSet.any qtrans + in + let nqtrans = + if QNameSet.is_empty rem then qtrans + else + (rem, Formula.false_) :: qtrans + in + Hashtbl.replace a.transitions q nqtrans ) a.states +(* [cleanup_states] remove states that do not lead to a + selecting states *) + let cleanup_states a = let memo = ref StateSet.empty in let rec loop q = @@ -308,13 +391,16 @@ let normalize_negations auto = in Hashtbl.add memo_state key nq; nq in - let trans = Hashtbl.find auto.transitions q in + let trans = try Hashtbl.find auto.transitions q with Not_found -> [] in let trans' = List.map (fun (lab, f) -> lab, flip b f) trans in Hashtbl.replace auto.transitions q' trans'; done; cleanup_states auto + + + module Builder = struct type auto = t @@ -326,6 +412,7 @@ module Builder = { id = next (); states = StateSet.empty; + starting_states = StateSet.empty; selecting_states = StateSet.empty; transitions = Hashtbl.create MED_H_SIZE; } @@ -350,8 +437,9 @@ module Builder = ); *) auto - let add_state a ?(selecting=false) q = + let add_state a ?(starting=false) ?(selecting=false) q = a.states <- StateSet.add q a.states; + if starting then a.starting_states <- StateSet.add q a.starting_states; if selecting then a.selecting_states <- StateSet.add q a.selecting_states let add_trans a q s f = @@ -383,3 +471,135 @@ module Builder = normalize_negations a; a end + + +let map_set f s = + StateSet.fold (fun q a -> StateSet.add (f q) a) s StateSet.empty + +let map_hash fk fv h = + let h' = Hashtbl.create (Hashtbl.length h) in + let () = Hashtbl.iter (fun k v -> Hashtbl.add h' (fk k) (fv v)) h in + h' + +let rec map_form f phi = + match Formula.expr phi with + | Boolean.Or(phi1, phi2) -> Formula.or_ (map_form f phi1) (map_form f phi2) + | Boolean.And(phi1, phi2) -> Formula.and_ (map_form f phi1) (map_form f phi2) + | Boolean.Atom({ Atom.node = Move(m,q); _}, b) -> + let a = Formula.mk_atom (Move (m,f q)) in + if b then a else Formula.not_ a + | _ -> phi + +let rename_states mapper a = + let rename q = try Hashtbl.find mapper q with Not_found -> q in + { Builder.make () with + states = map_set rename a.states; + starting_states = map_set rename a.starting_states; + selecting_states = map_set rename a.selecting_states; + transitions = + map_hash + rename + (fun l -> + (List.map (fun (labels, form) -> (labels, map_form rename form)) l)) + a.transitions; + } + +let copy a = + let mapper = Hashtbl.create MED_H_SIZE in + let () = + StateSet.iter (fun q -> Hashtbl.add mapper q (State.make())) a.states + in + rename_states mapper a + + +let concat a1 a2 = + let a1 = copy a1 in + let a2 = copy a2 in + let link_phi = + StateSet.fold + (fun q phi -> Formula.(or_ (stay q) phi)) + a1.selecting_states Formula.false_ + in + Hashtbl.iter (fun q trs -> Hashtbl.add a1.transitions q trs) + a2.transitions; + StateSet.iter + (fun q -> + Hashtbl.replace a1.transitions q [(QNameSet.any, link_phi)]) + a2.starting_states; + { a1 with + states = StateSet.union a1.states a2.states; + selecting_states = a2.selecting_states; + transitions = a1.transitions; + } + +let merge a1 a2 = + let a1 = copy a1 in + let a2 = copy a2 in + { a1 with + states = StateSet.union a1.states a2.states; + selecting_states = StateSet.union a1.selecting_states a2.selecting_states; + starting_states = StateSet.union a1.starting_states a2.starting_states; + transitions = + let () = + Hashtbl.iter (fun k v -> Hashtbl.add a1.transitions k v) a2.transitions + in + a1.transitions + } + + +let link a1 a2 q link_phi = + { a1 with + states = StateSet.union a1.states a2.states; + selecting_states = StateSet.singleton q; + starting_states = StateSet.union a1.starting_states a2.starting_states; + transitions = + let () = + Hashtbl.iter (fun k v -> Hashtbl.add a1.transitions k v) a2.transitions + in + Hashtbl.add a1.transitions q [(QNameSet.any, link_phi)]; + a1.transitions + } + +let union a1 a2 = + let a1 = copy a1 in + let a2 = copy a2 in + let q = State.make () in + let link_phi = + StateSet.fold + (fun q phi -> Formula.(or_ (stay q) phi)) + (StateSet.union a1.selecting_states a2.selecting_states) + Formula.false_ + in + link a1 a2 q link_phi + +let inter a1 a2 = + let a1 = copy a1 in + let a2 = copy a2 in + let q = State.make () in + let link_phi = + StateSet.fold + (fun q phi -> Formula.(and_ (stay q) phi)) + (StateSet.union a1.selecting_states a2.selecting_states) + Formula.true_ + in + link a1 a2 q link_phi + +let neg a = + let a = copy a in + let q = State.make () in + let link_phi = + StateSet.fold + (fun q phi -> Formula.(and_ (not_(stay q)) phi)) + a.selecting_states + Formula.true_ + in + let () = Hashtbl.add a.transitions q [(QNameSet.any, link_phi)] in + let a = + { a with + selecting_states = StateSet.singleton q; + } + in + normalize_negations a; a + +let diff a1 a2 = inter a1 (neg a2) +