-let create s ss = { id = next ();
- states = s;
- selection_states = ss;
- transitions = Hashtbl.create 17;
- cache2 = Cache.N2.create dummy2;
- cache6 = Cache.N6.create dummy6;
- }
-
-let reset a =
- a.cache2 <- Cache.N2.create dummy2;
- a.cache6 <- Cache.N6.create dummy6
-
-
-let get_trans_aux 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_trans a tag states =
- let trs =
- Cache.N2.find a.cache2
- (tag.QName.id :> int) (states.StateSet.id :> int)
- in
- if trs == dummy2 then
- let trs = get_trans_aux a tag states in
- (Cache.N2.add
- a.cache2
- (tag.QName.id :> int)
- (states.StateSet.id :> int) trs; trs)
- else trs
-
-
-
-let eval_form phi fcs nss ps ss is_left is_right has_left has_right kind =
- let rec loop phi =
- begin match SFormula.expr phi with
- Formula.True -> true
- | Formula.False -> false
- | Formula.Atom a ->
- let p, b, q = Atom.node a in
- let pos =
- match p with
- | First_child -> StateSet.mem q fcs
- | Next_sibling -> StateSet.mem q nss
- | Parent | Previous_sibling -> StateSet.mem q ps
- | Stay -> StateSet.mem q ss
- | Is_first_child -> is_left
- | Is_next_sibling -> is_right
- | Is k -> k == kind
- | Has_first_child -> has_left
- | Has_next_sibling -> has_right
- in
- if is_move p && (not b) then
- eprintf "Warning: Invalid negative atom %a" Atom.print a;
- b == pos
- | Formula.And(phi1, phi2) -> loop phi1 && loop phi2
- | Formula.Or (phi1, phi2) -> loop phi1 || loop phi2
- end
- in
- loop phi
-
-let int_of_conf is_left is_right has_left has_right kind =
- ((Obj.magic kind) lsl 4) lor
- ((Obj.magic is_left) lsl 3) lor
- ((Obj.magic is_right) lsl 2) lor
- ((Obj.magic has_left) lsl 1) lor
- (Obj.magic has_right)
-
-let eval_trans auto ltrs fcs nss ps ss is_left is_right has_left has_right kind =
- let i = int_of_conf is_left is_right has_left has_right kind
- and k = (fcs.StateSet.id :> int)
- and l = (nss.StateSet.id :> int)
- and m = (ps.StateSet.id :> int)
- in
-
- let rec loop ltrs ss =
- let j = (ltrs.TransList.id :> int)
- and n = (ss.StateSet.id :> int) in
- let (new_ltrs, new_ss) as res =
- let res = Cache.N6.find auto.cache6 i j k l m n in
- if res == dummy6 then
- let res =
- TransList.fold (fun trs (acct, accs) ->
- let q, _, phi = Transition.node trs in
- if StateSet.mem q accs then (acct, accs) else
- if eval_form
- phi fcs nss ps accs
- is_left is_right has_left has_right kind
- then
- (acct, StateSet.add q accs)
- else
- (TransList.cons trs acct, accs)
- ) ltrs (TransList.nil, ss)
- in
- Cache.N6.add auto.cache6 i j k l m n res; res
- else
- res
- in
- if new_ss == ss then res else
- loop new_ltrs new_ss
- in
- loop ltrs ss
-
-
-
-
-
-(*
- [add_trans a q labels f] adds a transition [(q,labels) -> f] to the
- automaton [a] but ensures that transitions remains pairwise disjoint
-*)
-
-let add_trans a q s f =
- let trs = try Hashtbl.find a.transitions q with Not_found -> [] in
- let cup, ntrs =
- List.fold_left (fun (acup, atrs) (labs, phi) ->
- let lab1 = QNameSet.inter labs s in
- let lab2 = QNameSet.diff labs s in
- let tr1 =
- if QNameSet.is_empty lab1 then []
- else [ (lab1, SFormula.or_ phi f) ]
- in
- let tr2 =
- if QNameSet.is_empty lab2 then []
- else [ (lab2, SFormula.or_ phi f) ]
- in
- (QNameSet.union acup labs, tr1@ tr2 @ atrs)
- ) (QNameSet.empty, []) trs
- in
- let rem = QNameSet.diff s cup in
- let ntrs = if QNameSet.is_empty rem then ntrs
- else (rem, f) :: ntrs
- in
- Hashtbl.replace a.transitions q ntrs