-(* Todo refactor and remove this alias *)
INCLUDE "debug.ml"
-module Tree = Tree.Binary
+INCLUDE "utils.ml"
+type jump_kind = [ `TAG of Tag.t | `CONTAINS of string | `NOTHING ]
-let gen_id =
- let id = ref (-1) in
- fun () -> incr id;!id
-
-
-module State = struct
+(* Todo : move elsewhere *)
+external vb : bool -> int = "%identity"
+module State :
+sig
+ include Sigs.T with type t = int
+ val make : unit -> t
+end =
+struct
type t = int
- let mk = gen_id
+ let make =
+ let id = ref (-1) in
+ fun () -> incr id;!id
+ let compare = (-)
+ let equal = (==)
+ external hash : t -> int = "%identity"
+ let print fmt x = Format.fprintf fmt "%i" x
+ let dump fmt x = print fmt x
+ let check x =
+ if x < 0 then failwith (Printf.sprintf "State: Assertion %i < 0 failed" x)
+end
+module StateSet = struct
+ include Ptset.Int
+ let print ppf s =
+ Format.pp_print_string ppf "{ ";
+ iter (fun i -> Format.fprintf ppf "%i " i) s;
+ Format.pp_print_string ppf "}";
+ Format.pp_print_flush ppf ()
end
-let mk_state = State.mk
+
+module Formula =
+struct
+ type 'hcons expr =
+ | False | True
+ | Or of 'hcons * 'hcons
+ | And of 'hcons * 'hcons
+ | Atom of ([ `Left | `Right | `LLeft | `RRight ]*bool*State.t)
+ type 'hcons node = {
+ pos : 'hcons expr;
+ mutable neg : 'hcons;
+ st : (StateSet.t*StateSet.t*StateSet.t)*(StateSet.t*StateSet.t*StateSet.t);
+ size: int; (* Todo check if this is needed *)
+ }
+
+ external hash_const_variant : [> ] -> int = "%identity"
+ module rec HNode : Hcons.S with type data = Node.t = Hcons.Make (Node)
+ and Node : Hashtbl.HashedType with type t = HNode.t node =
+ struct
+ type t = HNode.t node
+ let equal x y = x.size == y.size &&
+ match x.pos,y.pos with
+ | False,False
+ | True,True -> true
+ | Or(xf1,xf2),Or(yf1,yf2)
+ | And(xf1,xf2),And(yf1,yf2) -> (HNode.equal xf1 yf1) && (HNode.equal xf2 yf2)
+ | Atom(d1,p1,s1), Atom(d2,p2,s2) -> d1 == d2 && (p1==p2) && s1 == s2
+ | _ -> false
+ let hash f =
+ match f.pos with
+ | False -> 0
+ | True -> 1
+ | Or (f1,f2) -> HASHINT3(PRIME2,HNode.uid f1,HNode.uid f2)
+ | And (f1,f2) -> HASHINT3(PRIME3,HNode.uid f1,HNode.uid f2)
+ | Atom(d,p,s) -> HASHINT4(PRIME4,hash_const_variant d,vb p,s)
+ end
+
+ type t = HNode.t
+ let hash = HNode.hash
+ let uid = HNode.uid
+ let equal = HNode.equal
+ let expr f = (HNode.node f).pos
+ let st f = (HNode.node f ).st
+ let size f = (HNode.node f).size
+
+ let prio f =
+ match expr f with
+ | True | False -> 10
+ | Atom _ -> 8
+ | And _ -> 6
+ | Or _ -> 1
+
+ let rec print ?(parent=false) ppf f =
+ if parent then Format.fprintf ppf "(";
+ let _ = match expr f with
+ | True -> Format.fprintf ppf "T"
+ | False -> Format.fprintf ppf "F"
+ | And(f1,f2) ->
+ print ~parent:(prio f > prio f1) ppf f1;
+ Format.fprintf ppf " ∧ ";
+ print ~parent:(prio f > prio f2) ppf f2;
+ | Or(f1,f2) ->
+ (print ppf f1);
+ Format.fprintf ppf " ∨ ";
+ (print ppf f2);
+ | Atom(dir,b,s) -> Format.fprintf ppf "%s%s[%i]"
+ (if b then "" else "¬")
+ (match dir with
+ | `Left -> "↓₁"
+ | `Right -> "↓₂"
+ | `LLeft -> "⇓₁"
+ | `RRight -> "⇓₂") s
+ in
+ if parent then Format.fprintf ppf ")"
+
+ let print ppf f = print ~parent:false ppf f
+
+ let is_true f = (expr f) == True
+ let is_false f = (expr f) == False
+
+
+ let cons pos neg s1 s2 size1 size2 =
+ let nnode = HNode.make { pos = neg; neg = (Obj.magic 0); st = s2; size = size2 } in
+ let pnode = HNode.make { pos = pos; neg = nnode ; st = s1; size = size1 }
+ in
+ (HNode.node nnode).neg <- pnode; (* works because the neg field isn't taken into
+ account for hashing ! *)
+ pnode,nnode
+
+ let empty_triple = StateSet.empty,StateSet.empty,StateSet.empty
+ let empty_hex = empty_triple,empty_triple
+ let true_,false_ = cons True False empty_hex empty_hex 0 0
+ let atom_ d p s =
+ let si = StateSet.singleton s in
+ let ss = match d with
+ | `Left -> (si,StateSet.empty,si),empty_triple
+ | `Right -> empty_triple,(si,StateSet.empty,si)
+ | `LLeft -> (StateSet.empty,si,si),empty_triple
+ | `RRight -> empty_triple,(StateSet.empty,si,si)
+ in fst (cons (Atom(d,p,s)) (Atom(d,not p,s)) ss ss 1 1)
+
+ let not_ f = (HNode.node f).neg
+ let union_hex ((l1,ll1,lll1),(r1,rr1,rrr1)) ((l2,ll2,lll2),(r2,rr2,rrr2)) =
+ (StateSet.mem_union l1 l2 ,StateSet.mem_union ll1 ll2,StateSet.mem_union lll1 lll2),
+ (StateSet.mem_union r1 r2 ,StateSet.mem_union rr1 rr2,StateSet.mem_union rrr1 rrr2)
+
+ let merge_states f1 f2 =
+ let sp =
+ union_hex (st f1) (st f2)
+ and sn =
+ union_hex (st (not_ f1)) (st (not_ f2))
+ in
+ sp,sn
-type state = State.t
+ let order f1 f2 = if uid f1 < uid f2 then f2,f1 else f1,f2
-type predicate = [ `Left of (Tree.t -> bool) | `Right of (Tree.t -> bool) |
- `True
- ]
+ let or_ f1 f2 =
+ (* Tautologies: x|x, x|not(x) *)
-let eval_pred t =
- function `True -> true
- | `Left f | `Right f -> f t
-
-type formula_expr =
- | False | True
- | Or of formula * formula
- | And of formula * formula
- | Atom of ([ `Left | `Right | `LLeft | `RRight ]*bool*state)
-and formula = { fid: int;
- fkey : int;
- pos : formula_expr;
- neg : formula;
- st : (Ptset.t*Ptset.t)*(Ptset.t*Ptset.t);
- size: int;
- }
-
-external hash_const_variant : [> ] -> int = "%identity"
-external int_bool : bool -> int = "%identity"
-
-let hash_node_form t = match t with
- | False -> 0
- | True -> 1
- | And(f1,f2) -> (2+17*f1.fkey + 37*f2.fkey) land max_int
- | Or(f1,f2) -> (3+101*f1.fkey + 253*f2.fkey) land max_int
- | Atom(v,b,s) -> ((hash_const_variant v) + (3846*(int_bool b) +257) + (s lsl 13 - s)) land max_int
-
+ if equal f1 f2 then f1 else
+ if equal f1 (not_ f2) then true_ else
-module FormNode =
-struct
- type t = formula
-
- let hash t = t.fkey
- let equal f1 f2 =
- if f1.fid == f2.fid || f1.fkey == f2.fkey || f1.pos == f2.pos then true
- else
- match f1.pos,f2.pos with
- | False,False | True,True -> true
- | Atom(d1,b1,s1), Atom(d2,b2,s2) when (b1==b2) && (s1==s2) && (d1 = d2) -> true
- | Or(g1,g2),Or(h1,h2)
- | And(g1,g2),And(h1,h2) -> g1.fid == h1.fid && g2.fid == h2.fid
- | _ -> false
+ (* simplification *)
+ if is_true f1 || is_true f2 then true_ else
+ if is_false f1 && is_false f2 then false_ else
+ if is_false f1 then f2 else
+ if is_false f2 then f1 else
-end
-module WH = Weak.Make(FormNode)
-
-let f_pool = WH.create 107
-
-let empty_pair = Ptset.empty,Ptset.empty
-let empty_quad = empty_pair,empty_pair
-
-let true_,false_ =
- let rec t = { fid = 1; pos = True; fkey=1; neg = f ; st = empty_quad; size =1; }
- and f = { fid = 0; pos = False; fkey=0; neg = t; st = empty_quad; size = 1; }
- in
- WH.add f_pool f;
- WH.add f_pool t;
- t,f
-
-let is_true f = f.fid == 1
-let is_false f = f.fid == 0
-
-
-let cons pos neg s1 s2 size1 size2 =
- let rec pnode =
- { fid = gen_id ();
- fkey = hash_node_form pos;
- pos = pos;
- neg = nnode;
- st = s1;
- size = size1;}
- and nnode = {
- fid = gen_id ();
- pos = neg;
- fkey = hash_node_form neg;
- neg = pnode;
- st = s2;
- size = size2;
- }
- in
- (WH.merge f_pool pnode),(WH.merge f_pool nnode)
-
-let atom_ d p s =
- let si = Ptset.singleton s in
- let ss = match d with
- | `Left -> (si,Ptset.empty),empty_pair
- | `Right -> empty_pair,(si,Ptset.empty)
- | `LLeft -> (Ptset.empty,si),empty_pair
- | `RRight -> empty_pair,(Ptset.empty,si)
- in fst (cons (Atom(d,p,s)) (Atom(d,not p,s)) ss ss 1 1)
-
-let union_quad ((l1,ll1),(r1,rr1)) ((l2,ll2),(r2,rr2)) =
- (Ptset.union l1 l2 ,Ptset.union ll1 ll2),
- (Ptset.union r1 r2 ,Ptset.union rr1 rr2)
-
-let merge_states f1 f2 =
- let sp =
- union_quad f1.st f2.st
- and sn =
- union_quad f1.neg.st f2.neg.st
- in
- sp,sn
+ (* commutativity of | *)
-let full_or_ f1 f2 =
- let f1,f2 = if f1.fid < f2.fid then f2,f1 else f1,f2 in
- let sp,sn = merge_states f1 f2 in
- let psize = f1.size + f2.size in
- let nsize = f1.neg.size + f2.neg.size in
- fst (cons (Or(f1,f2)) (And(f1.neg,f2.neg)) sp sn psize nsize )
-
-let or_ f1 f2 =
- let f1,f2 = if f1.fid < f2.fid then f2,f1 else f1,f2 in
- if is_true f1 || is_true f2 then true_
- else if is_false f1 && is_false f2 then false_
- else if is_false f1 then f2
- else if is_false f2 then f1
- else
- let psize = f1.size + f2.size in
- let nsize = f1.neg.size + f2.neg.size in
- let sp,sn = merge_states f1 f2 in
- fst (cons (Or(f1,f2)) (And(f1.neg,f2.neg)) sp sn psize nsize)
-
-
-
-let and_ f1 f2 =
- let f1,f2 = if f1.fid < f2.fid then f2,f1 else f1,f2 in
- if is_true f1 && is_true f2 then true_
- else if is_false f1 || is_false f2 then false_
- else if is_true f1 then f2
- else if is_true f2 then f1
- else
- let psize = f1.size + f2.size in
- let nsize = f1.neg.size + f2.neg.size in
- let sp,sn = merge_states f1 f2 in
- fst (cons (And(f1,f2)) (Or(f1.neg,f2.neg)) sp sn psize nsize)
-
+ let f1,f2 = order f1 f2 in
+ let psize = (size f1) + (size f2) in
+ let nsize = (size (not_ f1)) + (size (not_ f2)) in
+ let sp,sn = merge_states f1 f2 in
+ fst (cons (Or(f1,f2)) (And(not_ f1,not_ f2)) sp sn psize nsize)
+
+
+ let and_ f1 f2 =
+
+ (* Tautologies: x&x, x¬(x) *)
+
+ if equal f1 f2 then f1 else
+ if equal f1 (not_ f2) then false_ else
+
+ (* simplifications *)
+
+ if is_true f1 && is_true f2 then true_ else
+ if is_false f1 || is_false f2 then false_ else
+ if is_true f1 then f2 else
+ if is_true f2 then f1 else
+
+ (* commutativity of & *)
+
+ let f1,f2 = order f1 f2 in
+ let psize = (size f1) + (size f2) in
+ let nsize = (size (not_ f1)) + (size (not_ f2)) in
+ let sp,sn = merge_states f1 f2 in
+ fst (cons (And(f1,f2)) (Or(not_ f1,not_ f2)) sp sn psize nsize)
+ module Infix = struct
+ let ( +| ) f1 f2 = or_ f1 f2
+ let ( *& ) f1 f2 = and_ f1 f2
+ let ( *+ ) d s = atom_ d true s
+ let ( *- ) d s = atom_ d false s
+ end
+end
+
+module Transition = struct
+
+ type node = State.t*bool*Formula.t*bool
+ include Hcons.Make(struct
+ type t = node
+ let hash (s,m,f,b) = HASHINT4(s,Formula.uid f,vb m,vb b)
+ let equal (s,b,f,m) (s',b',f',m') =
+ s == s' && b==b' && m==m' && Formula.equal f f'
+ end)
+
+ let print ppf f = let (st,mark,form,b) = node f in
+ Format.fprintf ppf "%i %s" st (if mark then "⇒" else "→");
+ Formula.print ppf form;
+ Format.fprintf ppf "%s%!" (if b then " (b)" else "")
-let not_ f = f.neg
+ module Infix = struct
+ let ( ?< ) x = x
+ let ( >< ) state (l,mark) = state,(l,mark,false)
+ let ( ><@ ) state (l,mark) = state,(l,mark,true)
+ let ( >=> ) (state,(label,mark,bur)) form = (state,label,(make (state,mark,form,bur)))
+ end
+
+end
-module HTagSetKey =
+module SetTagKey =
struct
- type t = Ptset.t*Tag.t
- let int_hash key = key lsl 31 lor (key lsl 8)
- let equal (s1,s2) (t1,t2) = (s2 == t2) && Ptset.equal s1 t1
- let hash (s,t) = int_hash (Ptset.hash s) lxor ( int_hash (Tag.hash t))
+ type t = Ptset.Int.t*Tag.t
+ let equal (s1,t1) (s2,t2) = (t1 == t2) && Ptset.Int.equal s1 s2
+ let hash (s,t) = HASHINT2(Ptset.Int.uid s, t)
+end
+
+module TransTable = Hashtbl
+module CachedTransTable = Hashtbl.Make(SetTagKey)
+
+module Formlist = struct
+ include Hlist.Make(Transition)
+ let print ppf fl =
+ iter (fun t -> Transition.print ppf t; Format.pp_print_newline ppf ()) fl
end
-module HTagSet = Hashtbl.Make(HTagSetKey)
-type t = {
+
+type 'a t = {
id : int;
- mutable states : Ptset.t;
- init : Ptset.t;
- mutable final : Ptset.t;
- universal : Ptset.t;
+ mutable states : Ptset.Int.t;
+ init : Ptset.Int.t;
+ starstate : Ptset.Int.t option;
(* Transitions of the Alternating automaton *)
- phi : (state,(TagSet.t*(bool*formula*predicate)) list) Hashtbl.t;
- delta : (state*Tag.t, (bool*formula*predicate)) Hashtbl.t;
-(* delta : (state,(bool*formula*predicate) TagMap.t) Hashtbl.t; *)
- sigma : (bool*formula*(predicate list*predicate list)*bool) HTagSet.t;
- }
-
- module Pair (X : Set.OrderedType) (Y : Set.OrderedType) =
- struct
- type t = X.t*Y.t
- let compare (x1,y1) (x2,y2) =
- let r = X.compare x1 x2 in
- if r == 0 then Y.compare y1 y2
- else r
- end
+ trans : (State.t,(TagSet.t*Transition.t) list) Hashtbl.t;
+ query_string: string;
+ }
- module PL = Set.Make (Pair (Ptset) (Ptset))
-
-
- let pr_st ppf l = Format.fprintf ppf "{";
- begin
- match l with
- | [] -> ()
- | [s] -> Format.fprintf ppf " %i" s
- | p::r -> Format.fprintf ppf " %i" p;
- List.iter (fun i -> Format.fprintf ppf "; %i" i) r
- end;
- Format.fprintf ppf " }"
- let rec pr_frm ppf f = match f.pos with
- | True -> Format.fprintf ppf "⊤"
- | False -> Format.fprintf ppf "⊥"
- | And(f1,f2) ->
- Format.fprintf ppf "(";
- (pr_frm ppf f1);
- Format.fprintf ppf ") ∧ (";
- (pr_frm ppf f2);
- Format.fprintf ppf ")"
- | Or(f1,f2) ->
- (pr_frm ppf f1);
- Format.fprintf ppf " ∨ ";
- (pr_frm ppf f2);
- | Atom(dir,b,s) -> Format.fprintf ppf "%s%s[%i]"
- (if b then "" else "¬")
- (match dir with
- | `Left -> "↓₁"
- | `Right -> "↓₂"
- | `LLeft -> "⇓₁"
- | `RRight -> "⇓₂") s
-
- let dnf_hash = Hashtbl.create 17
-
- let rec dnf_aux f = match f.pos with
- | False -> PL.empty
- | True -> PL.singleton (Ptset.empty,Ptset.empty)
- | Atom((`Left|`LLeft),_,s) -> PL.singleton (Ptset.singleton s,Ptset.empty)
- | Atom((`Right|`RRight),_,s) -> PL.singleton (Ptset.empty,Ptset.singleton s)
- | Or(f1,f2) -> PL.union (dnf f1) (dnf f2)
- | And(f1,f2) ->
- let pl1 = dnf f1
- and pl2 = dnf f2
- in
- PL.fold (fun (s1,s2) acc ->
- PL.fold ( fun (s1', s2') acc' ->
- (PL.add
- ((Ptset.union s1 s1'),
- (Ptset.union s2 s2')) acc') )
- pl2 acc )
- pl1 PL.empty
-
-
- and dnf f =
- try
- Hashtbl.find dnf_hash f.fid
- with
- Not_found ->
- let d = dnf_aux f in
- Hashtbl.add dnf_hash f.fid d;d
-
-
- let can_top_down f =
- let nf = dnf f in
- if (PL.cardinal nf > 3)then None
- else match PL.elements nf with
- | [(s1,s2); (t1,t2); (u1,u2)] when
- Ptset.is_empty s1 && Ptset.is_empty s2 && Ptset.is_empty t1 && Ptset.is_empty u2
- -> Some(true,t2,u1)
- | [(t1,t2); (u1,u2)] when Ptset.is_empty t1 && Ptset.is_empty u2
- -> Some(false,t2,u1)
- | _ -> None
-
-
- let equal_form f1 f2 =
- (f1.fid == f2.fid) || (FormNode.equal f1 f2) || (PL.equal (dnf f1) (dnf f2))
-
- let dump ppf a =
- Format.fprintf ppf "Automaton (%i) :\n" a.id;
- Format.fprintf ppf "States : "; pr_st ppf (Ptset.elements a.states);
- Format.fprintf ppf "\nInitial states : "; pr_st ppf (Ptset.elements a.init);
- Format.fprintf ppf "\nFinal states : "; pr_st ppf (Ptset.elements a.final);
- Format.fprintf ppf "\nUniversal states : "; pr_st ppf (Ptset.elements a.universal);
- Format.fprintf ppf "\nAlternating transitions :\n------------------------------\n";
- let l = Hashtbl.fold (fun k t acc ->
- (List.map (fun (t,(m,f,p)) -> (t,k),(m,f,p)) t)@ acc) a.phi [] in
- let l = List.sort (fun ((tsx,x),_) ((tsy,y),_) -> if x-y == 0 then TagSet.compare tsx tsy else x-y) l in
- List.iter (fun ((ts,q),(b,f,_)) ->
-
- let s =
- if TagSet.is_finite ts
- then "{" ^ (TagSet.fold (fun t a -> a ^ " '" ^ (Tag.to_string t)^"'") ts "") ^" }"
- else let cts = TagSet.neg ts in
- if TagSet.is_empty cts then "*" else
- (TagSet.fold (fun t a -> a ^ " " ^ (Tag.to_string t)) cts "*\\{"
- )^ "}"
- in
- Format.fprintf ppf "(%s,%i) %s " s q (if b then "=>" else "->");
- pr_frm ppf f;
- Format.fprintf ppf "\n")l;
-
- Format.fprintf ppf "NFA transitions :\n------------------------------\n";
- HTagSet.iter (fun (qs,t) (b,f,_,_) ->
- pr_st ppf (Ptset.elements qs);
- Format.fprintf ppf ",%s %s " (Tag.to_string t) (if b then "=>" else "->");
- pr_frm ppf f;
- Format.fprintf ppf "(fid=%i) left=" f.fid;
- let (l,ll),(r,rr) = f.st in
- pr_st ppf (Ptset.elements l);
- Format.fprintf ppf ", ";
- pr_st ppf (Ptset.elements ll);
- Format.fprintf ppf ", right=";
- pr_st ppf (Ptset.elements r);
- Format.fprintf ppf ", ";
- pr_st ppf (Ptset.elements rr);
- Format.fprintf ppf "\n";
- ) a.sigma;
- Format.fprintf ppf "=======================================\n"
+
+let dump ppf a =
+ Format.fprintf ppf "Automaton (%i) :\n" a.id;
+ Format.fprintf ppf "States : "; StateSet.print ppf a.states;
+ Format.fprintf ppf "\nInitial states : "; StateSet.print ppf a.init;
+ Format.fprintf ppf "\nAlternating transitions :\n";
+ let l = Hashtbl.fold (fun k t acc ->
+ (List.map (fun (ts,tr) -> (ts,k),Transition.node tr) t) @ acc) a.trans [] in
+ let l = List.sort (fun ((tsx,x),_) ((tsy,y),_) ->
+ if y-x == 0 then TagSet.compare tsy tsx else y-x) l in
+ let maxh,maxt,l_print =
+ List.fold_left (
+ fun (maxh,maxt,l) ((ts,q),(_,b,f,_)) ->
+ let s =
+ if TagSet.is_finite ts
+ then "{" ^ (TagSet.fold (fun t a -> a ^ " '" ^ (Tag.to_string t)^"'") ts "") ^" }"
+ else let cts = TagSet.neg ts in
+ if TagSet.is_empty cts then "*" else
+ (TagSet.fold (fun t a -> a ^ " " ^ (Tag.to_string t)) cts "*\\{"
+ )^ "}"
+ in
+ let s = Printf.sprintf "(%s,%i)" s q in
+ let s_frm =
+ Formula.print Format.str_formatter f;
+ Format.flush_str_formatter()
+ in
+ (max (String.length s) maxh, max (String.length s_frm) maxt,
+ (s,(if b then "⇒" else "→"),s_frm)::l)) (0,0,[]) l
+ in
+ Format.fprintf ppf "%s\n%!" (String.make (maxt+maxh+3) '_');
+ List.iter (fun (s,m,f) -> let s = s ^ (String.make (maxh-(String.length s)) ' ') in
+ Format.fprintf ppf "%s %s %s\n" s m f) l_print;
+ Format.fprintf ppf "%s\n%!" (String.make (maxt+maxh+3) '_')
- module Transitions = struct
- type t = state*TagSet.t*bool*formula*predicate
- let ( ?< ) x = x
- let ( >< ) state (l,b) = state,(l,b,`True)
- let ( ><@ ) state (l,b,p) = state,(l,b,p)
- let ( >=> ) (state,(label,mark,pred)) form = (state,label,mark,form,pred)
- let ( +| ) f1 f2 = or_ f1 f2
- let ( *& ) f1 f2 = and_ f1 f2
- let ( ** ) d s = atom_ d true s
+module FormTable = Hashtbl.Make(struct
+ type t = Formula.t*StateSet.t*StateSet.t
+ let equal (f1,s1,t1) (f2,s2,t2) =
+ Formula.equal f1 f2 && StateSet.equal s1 s2 && StateSet.equal t1 t2
+ let hash (f,s,t) =
+ HASHINT3(Formula.uid f ,StateSet.uid s,StateSet.uid t)
+ end)
+(* Too slow
+module MemoForm = Memoizer.Make(
+
+module F = Formula
+(*
+let eval_form_bool =
+ MemoForm.make_rec(
+ fun eval (f, ((s1,s2) as sets)) ->
+ match F.expr f with
+ | F.True -> true,true,true
+ | F.False -> false,false,false
+ | F.Atom((`Left|`LLeft),b,q) ->
+ if b == (StateSet.mem q s1)
+ then (true,true,false)
+ else false,false,false
+ | F.Atom(_,b,q) ->
+ if b == (StateSet.mem q s2)
+ then (true,false,true)
+ else false,false,false
+ | F.Or(f1,f2) ->
+ let b1,rl1,rr1 = eval (f1,sets)
+ in
+ if b1 && rl1 && rr1 then (true,true,true) else
+ let b2,rl2,rr2 = eval (f2,sets) in
+ let rl1,rr1 = if b1 then rl1,rr1 else false,false
+ and rl2,rr2 = if b2 then rl2,rr2 else false,false
+ in (b1 || b2, rl1||rl2,rr1||rr2)
+
+ | F.And(f1,f2) ->
+ let b1,rl1,rr1 = eval (f1,sets) in
+ if b1 && rl1 && rr1 then (true,true,true) else
+ if b1 then
+ let b2,rl2,rr2 = eval (f2,sets) in
+ if b2 then (true,rl1||rl2,rr1||rr2) else (false,false,false)
+ else (false,false,false)
+ )
+
+*) *)
+module F = Formula
+
+let eval_form_bool =
+ let h_f = FormTable.create BIG_H_SIZE in
+ fun f s1 s2 ->
+ let rec loop f =
+ match F.expr f with
+ | F.True -> true,true,true
+ | F.False -> false,false,false
+ | F.Atom((`Left|`LLeft),b,q) ->
+ if b == (StateSet.mem q s1)
+ then (true,true,false)
+ else false,false,false
+ | F.Atom(_,b,q) ->
+ if b == (StateSet.mem q s2)
+ then (true,false,true)
+ else false,false,false
+ | f' ->
+ try FormTable.find h_f (f,s1,s2)
+ with Not_found -> let r =
+ match f' with
+ | F.Or(f1,f2) ->
+ let b1,rl1,rr1 = loop f1
+ in
+ if b1 && rl1 && rr1 then (true,true,true) else
+ let b2,rl2,rr2 = loop f2 in
+ let rl1,rr1 = if b1 then rl1,rr1 else false,false
+ and rl2,rr2 = if b2 then rl2,rr2 else false,false
+ in (b1 || b2, rl1||rl2,rr1||rr2)
+
+ | F.And(f1,f2) ->
+ let b1,rl1,rr1 = loop f1 in
+ if b1 && rl1 && rr1 then (true,true,true) else
+ if b1 then
+ let b2,rl2,rr2 = loop f2 in
+ if b2 then (true,rl1||rl2,rr1||rr2) else (false,false,false)
+ else (false,false,false)
+ | _ -> assert false
+ in FormTable.add h_f (f,s1,s2) r;r
+ in loop f
+
+module FTable = Hashtbl.Make(
+ struct
+ type t = Formlist.t*StateSet.t*StateSet.t
+ let equal (f1,s1,t1) (f2,s2,t2) =
+ Formlist.equal f1 f2 && StateSet.equal s1 s2 && StateSet.equal t1 t2;;
+ let hash (f,s,t) = HASHINT3(Formlist.uid f ,StateSet.uid s,StateSet.uid t);;
+ end)
+
+(*
+module MemoFormlist = Memoizer.Make(FTable)
+
+ Too slow
+ let eval_formlist = MemoFormlist.make_rec (
+ fun eval (fl,((s1,s2)as sets)) ->
+ match Formlist.node fl with
+ | Formlist.Nil -> StateSet.empty,false,false,false,false
+ | Formlist.Cons(f,fll) ->
+ let q,mark,f,_ = Transition.node f in
+ let b,b1,b2 = eval_form_bool f s1 s2 in
+ let s,b',b1',b2',amark = eval (fll,sets) in
+ if b then (StateSet.add q s, b, b1'||b1,b2'||b2,mark||amark)
+ else s,b',b1',b2',amark )
+*)
- end
- type transition = Transitions.t
- let equal_trans (q1,t1,m1,f1,_) (q2,t2,m2,f2,_) =
- (q1 == q2) && (TagSet.equal t1 t2) && (m1 == m2) && (equal_form f1 f2)
-
- module TS =
- struct
- type node = Nil | Cons of Tree.t * node | Concat of node*node
- and t = { node : node; size : int }
- let node n s = { node=n; size = s }
- let empty = node Nil 0
+ let eval_formlist =
+ let h_f = FTable.create BIG_H_SIZE in
+ fun s1 s2 fl ->
+ let rec loop fl =
+ let key = (fl,s1,s2) in
+ try
+ FTable.find h_f key
+ with
+ | Not_found ->
+ match Formlist.node fl with
+ | Formlist.Nil -> StateSet.empty,false,false,false,false
+ | Formlist.Cons(f,fll) ->
+ let q,mark,f,_ = Transition.node f in
+ let b,b1,b2 = eval_form_bool f s1 s2 in
+ let s,b',b1',b2',amark = loop fll in
+ let r = if b then (StateSet.add q s, b, b1'||b1,b2'||b2,mark||amark)
+ else s,b',b1',b2',amark
+ in FTable.add h_f key r;r
+ in loop fl
+
+ let tags_of_state a q =
+ Hashtbl.fold
+ (fun p l acc ->
+ if p == q then List.fold_left
+ (fun acc (ts,t) ->
+ let _,_,_,aux = Transition.node t in
+ if aux then acc else
+ TagSet.cup ts acc) acc l
+
+ else acc) a.trans TagSet.empty
- let cons e t = node (Cons(e,t.node)) (t.size+1)
- let concat t1 t2 = node (Concat (t1.node,t2.node)) (t1.size+t2.size)
- let append = cons
-(* let append e t = node (Concat(t.node,Cons(e,Nil))) (t.size+1) *)
- let to_list_rev t =
- let rec aux acc l rest =
- match l with
- | Nil -> begin
- match rest with
- | Nil -> acc
- | Cons(e,t) -> aux (e::acc) t Nil
- | Concat(t1,t2) -> aux acc t1 t2
- end
- | Cons(e,r) -> aux (e::acc) r rest
- | Concat(t1,t2) -> aux acc t1 (Concat(t2,rest))
- in
- aux [] t.node Nil
-
- let length = function { size = s } -> s
-
- let iter f { node = n } =
- let rec loop = function
- | Nil -> ()
- | Cons(e,n) -> let _ = f e in loop n
- | Concat(n1,n2) -> let _ = loop n1 in loop n2
- in loop n
-
- let rev_iter f { node = n } =
- let rec loop = function
- | Nil -> ()
- | Cons(e,n) -> let _ = loop n in f e
- | Concat(n1,n2) -> let _ = loop n2 in loop n1
- in loop n
-
-
- let find f { node = n } =
- let rec loop = function
- | Nil -> raise Not_found
- | Cons(e,n) -> if f e then e else loop n
- | Concat(n1,n2) -> try
- loop n1
- with
- | Not_found -> loop n2
- in
- loop n
- end
-(*
- module BottomUpJumpNew = struct
-
-*)
- module HFEval = Hashtbl.Make(
- struct
- type t = int*Ptset.t*Ptset.t
- let equal (a,b,c) (d,e,f) =
- a==d && (Ptset.equal b e) && (Ptset.equal c f)
- let hash (a,b,c) =
- a+17*(Ptset.hash b) + 31*(Ptset.hash c)
- end)
-
- let hfeval = HFEval.create 4097
-
-
- let eval_form_bool f s1 s2 =
- let rec eval f = match f.pos with
- | Atom((`Left|`LLeft),b,q) -> if b == (Ptset.mem q s1) then (true,true,false) else false,false,false
- | Atom((`Right|`RRight),b,q) -> if b == (Ptset.mem q s2) then (true,false,true) else false,false,false
- (* test some inlining *)
- | True -> true,true,true
- | False -> false,false,false
- | _ ->
- try
- HFEval.find hfeval (f.fid,s1,s2)
- with
- | Not_found -> let r =
- match f.pos with
- | Or(f1,f2) ->
- let b1,rl1,rr1 = eval f1
- in
- if b1 && rl1 && rr1 then (true,true,true)
- else
- let b2,rl2,rr2 = eval f2
- in
- let rl1,rr1 = if b1 then rl1,rr1 else false,false
- and rl2,rr2 = if b2 then rl2,rr2 else false,false
- in (b1 || b2, rl1||rl2,rr1||rr2)
- | And(f1,f2) ->
- let b1,rl1,rr1 = eval f1 in
- if b1 && rl1 && rr1 then (true,true,true)
- else if b1
- then let b2,rl2,rr2 = eval f2 in
- if b2 then (true,rl1||rl2,rr1||rr2)
- else (false,false,false)
- else (false,false,false)
- | _ -> assert false
- in
- HFEval.add hfeval (f.fid,s1,s2) r;
- r
- in eval f
-
-
- let fstate_pool = Hashtbl.create 11
-
- let merge_pred a b = match a,b with
- | Some(f1), Some(f2) -> Some(fun x -> f1 x || f2 x)
- | None,None -> None
- | None,Some(_) -> b
- | Some(_),None -> a
-
- let acc_pred p l1 l2 = match p with
- | `Left _ -> p::l1,l2
- | `Right _ -> l1,p::l2
- | _ -> l1,l2
-
-
- let merge_trans t a tag q acc =
- List.fold_left (fun (accf,accm,acchtrue) (ts,(m,f,pred)) ->
- if TagSet.mem tag ts
- then
- let tmpf,hastrue =
- if is_true f then
- let newfinal =
- try Hashtbl.find fstate_pool f.fid with
- | Not_found -> let s = mk_state() in
- a.states <- Ptset.add s a.states;
- a.final <- Ptset.add s a.final;
- Hashtbl.add fstate_pool f.fid s;s
- in
- (atom_ `Left true newfinal),true
- else f,false in
- (or_ tmpf accf,accm||m,acchtrue||hastrue)
- else (accf,accm,acchtrue)
- ) acc (try Hashtbl.find a.phi q with Not_found -> [])
-
- let get_trans t a tag r =
- try
- let mark,f,predl,has_true =
- HTagSet.find a.sigma (r,tag)
- in f.st,f,mark,has_true,r
- with
- Not_found ->
- let f,mark,has_true,accq =
- Ptset.fold (fun q (accf,accm,acchtrue,accq) ->
- let naccf,naccm,nacctrue =
- merge_trans t a tag q (accf,accm,acchtrue )
- in
- if is_false naccf then (naccf,naccm,nacctrue,accq)
- else (naccf,naccm,nacctrue,Ptset.add q accq)
- )
- r (false_,false,false,Ptset.empty)
- in
- HTagSet.add a.sigma (accq,tag) (mark,f,([],[]),has_true);
- f.st,f,mark,has_true,accq
-
- let h_union = Hashtbl.create 4097
+ let tags a qs =
+ let ts = Ptset.Int.fold (fun q acc -> TagSet.cup acc (tags_of_state a q)) qs TagSet.empty
+ in
+ if TagSet.is_finite ts
+ then `Positive(TagSet.positive ts)
+ else `Negative(TagSet.negative ts)
+
+ let inter_text a b =
+ match b with
+ | `Positive s -> let r = Ptset.Int.inter a s in (r,Ptset.Int.mem Tag.pcdata r, true)
+ | `Negative s -> let r = Ptset.Int.diff a s in (r, Ptset.Int.mem Tag.pcdata r, false)
+
+ let mk_nil_ctx x _ = Tree.mk_nil x
+ let next_sibling_ctx x _ = Tree.next_sibling x
+ let r_ignore _ x = x
- let pt_cup s1 s2 =
- let h = (Ptset.hash s1,Ptset.hash s2) in
- try
- Hashtbl.find h_union h
- with
- | Not_found -> let s = Ptset.union s1 s2
- in
- Hashtbl.add h_union h s;s
+ module type ResultSet =
+ sig
+ type t
+ val empty : t
+ val cons : Tree.t -> t -> t
+ val concat : t -> t -> t
+ val iter : (Tree.t -> unit) -> t -> unit
+ val fold : (Tree.t -> 'a -> 'a) -> t -> 'a -> 'a
+ val map : (Tree.t -> Tree.t) -> t -> t
+ val length : t -> int
+ end
+
+ module Integer : ResultSet =
+ struct
+ type t = int
+ let empty = 0
+ let cons _ x = x+1
+ let concat x y = x + y
+ let iter _ _ = failwith "iter not implemented"
+ let fold _ _ _ = failwith "fold not implemented"
+ let map _ _ = failwith "map not implemented"
+ let length x = x
+ end
+
+ module IdSet : ResultSet =
+ struct
+ type node = Nil
+ | Cons of Tree.t * node
+ | Concat of node*node
+
+ and t = { node : node;
+ length : int }
+
+ let empty = { node = Nil; length = 0 }
+
+ let cons e t = { node = Cons(e,t.node); length = t.length+1 }
+ let concat t1 t2 = { node = Concat(t1.node,t2.node); length = t1.length+t2.length }
+ let append e t = { node = Concat(t.node,Cons(e,Nil)); length = t.length+1 }
+
+ let fold f l acc =
+ let rec loop acc t = match t with
+ | Nil -> acc
+ | Cons (e,t) -> loop (f e acc) t
+ | Concat (t1,t2) -> loop (loop acc t1) t2
+ in
+ loop acc l.node
+
+ let length l = l.length
+
+
+ let iter f l =
+ let rec loop = function
+ | Nil -> ()
+ | Cons (e,t) -> f e; loop t
+ | Concat(t1,t2) -> loop t1;loop t2
+ in loop l.node
+
+ let map f l =
+ let rec loop = function
+ | Nil -> Nil
+ | Cons(e,t) -> Cons(f e, loop t)
+ | Concat(t1,t2) -> Concat(loop t1,loop t2)
+ in
+ { l with node = loop l.node }
-
- let tags_of_state a q = Hashtbl.fold
- (fun p l acc ->
- if p == q then
- List.fold_left
- (fun acc (ts,_) ->
- pt_cup (TagSet.positive ts) acc) acc l
- else acc) a.phi Ptset.empty
-
- let h_tags_states = Hashtbl.create 4096
-
+
+ end
+ module Run (RS : ResultSet) =
+ struct
+ module SList = Hlist.Make (StateSet)
- let tags a qs =
- try
- Hashtbl.find h_tags_states (Ptset.hash qs)
- with
- | Not_found ->
- let l = Ptset.fold (fun q acc -> pt_cup acc (tags_of_state a q)) qs Ptset.empty
- in
- Hashtbl.add h_tags_states (Ptset.hash qs) l;l
-
- let time cpt acc f x =
- let t1 = Unix.gettimeofday () in
- let r = f x in
- let t2 = Unix.gettimeofday () in
- let t = (1000. *.(t2 -. t1)) in
- acc:=!acc+.t;
- incr cpt;
- r
-
-
- let h_time = Hashtbl.create 4096
- let calls = ref 0
- let rtime s f x =
-
- let cpt,atime =
+
+IFDEF DEBUG
+THEN
+ module IntSet = Set.Make(struct type t = int let compare = (-) end)
+INCLUDE "html_trace.ml"
+
+END
+
+ let td_trans = Hashtbl.create 4096
+ let mk_fun f s = D_IGNORE_(register_funname f s,f)
+ let mk_app_fun f arg s = let g = f arg in
+ D_IGNORE_(register_funname g ((get_funname f) ^ " " ^ s), g)
+
+ let string_of_ts tags = (Ptset.Int.fold (fun t a -> a ^ " " ^ (Tag.to_string t) ) tags "{")^ " }"
+
+ let choose_jump tagset qtags1 qtagsn a f_nil f_text f_t1 f_s1 f_tn f_sn f_notext =
+ let tags1,hastext1,fin1 = inter_text tagset (tags a qtags1) in
+ let tagsn,hastextn,finn = inter_text tagset (tags a qtagsn) in
+ if (hastext1||hastextn) then f_text (* jumping to text nodes doesn't work really well *)
+ else if (Ptset.Int.is_empty tags1) && (Ptset.Int.is_empty tagsn) then f_nil
+ else if (Ptset.Int.is_empty tagsn) then
+ if (Ptset.Int.is_singleton tags1)
+ then (* TaggedChild/Sibling *)
+ let tag = (Ptset.Int.choose tags1) in mk_app_fun f_t1 tag (Tag.to_string tag)
+ else (* SelectChild/Sibling *)
+ mk_app_fun f_s1 tags1 (string_of_ts tags1)
+ else if (Ptset.Int.is_empty tags1) then
+ if (Ptset.Int.is_singleton tagsn)
+ then (* TaggedDesc/Following *)
+ let tag = (Ptset.Int.choose tagsn) in mk_app_fun f_tn tag (Tag.to_string tag)
+ else (* SelectDesc/Following *)
+ mk_app_fun f_sn tagsn (string_of_ts tagsn)
+ else f_notext
+
+ let choose_jump_down a b c d =
+ choose_jump a b c d
+ (mk_fun (Tree.mk_nil) "Tree.mk_nil")
+ (mk_fun (Tree.text_below) "Tree.text_below")
+ (mk_fun (fun _ -> Tree.node_child) "[TaggedChild]Tree.node_child") (* !! no tagged_child in Tree.ml *)
+ (mk_fun (fun _ -> Tree.node_child) "[SelectChild]Tree.node_child") (* !! no select_child in Tree.ml *)
+ (mk_fun (Tree.tagged_desc) "Tree.tagged_desc")
+ (mk_fun (fun _ -> Tree.node_child ) "[SelectDesc]Tree.node_child") (* !! no select_desc *)
+ (mk_fun (Tree.node_child) "Tree.node_child")
+
+ let choose_jump_next a b c d =
+ choose_jump a b c d
+ (mk_fun (fun t _ -> Tree.mk_nil t) "Tree.mk_nil2")
+ (mk_fun (Tree.text_next) "Tree.text_next")
+ (mk_fun (fun _ -> Tree.node_sibling_ctx) "[TaggedSibling]Tree.node_sibling_ctx")(* !! no tagged_sibling in Tree.ml *)
+ (mk_fun (fun _ -> Tree.node_sibling_ctx) "[SelectSibling]Tree.node_sibling_ctx")(* !! no select_sibling in Tree.ml *)
+ (mk_fun (Tree.tagged_foll_ctx) "Tree.tagged_foll_ctx")
+ (mk_fun (fun _ -> Tree.node_sibling_ctx) "[SelectFoll]Tree.node_sibling_ctx")(* !! no select_foll *)
+ (mk_fun (Tree.node_sibling_ctx) "Tree.node_sibling_ctx")
+
+ let get_trans slist tag a t =
try
- Hashtbl.find h_time s
+ Hashtbl.find td_trans (tag,SList.hash slist)
with
- | _ -> (ref 0, ref 0.)
- in
- let r = time cpt atime f x
- in
- Hashtbl.replace h_time s (cpt,atime);
- r
-
- let rec accepting_among_time a t r ctx =
- incr calls;
- let orig = r in
- let rest = Ptset.inter r a.final in
- let r = Ptset.diff r rest in
- if Ptset.is_empty r then rest,TS.empty else
- if Tree.is_node t
- then
- let among,result,form =
- let ((ls,lls),(rs,rrs)),formula,mark,has_true,r' =
- let tag = rtime "Tree.tag" Tree.tag t in
- rtime "get_trans" (get_trans t a tag) r
- in
- let tl = rtime "tags" (tags a) ls
- and tr = rtime "tags" (tags a) rs
- and tll = rtime "tags" (tags a) lls
- and trr = rtime "tags" (tags a) rrs
- in
- let first =
- if Ptset.mem Tag.pcdata (pt_cup tl tll)
- then
- rtime "Tree.text_below" (Tree.text_below) t
- else
- let etl = Ptset.is_empty tl
- and etll = Ptset.is_empty tll
- in
- if etl && etll
- then Tree.mk_nil t
- else
- if etl then rtime "Tree.tagged_desc_only" (Tree.tagged_desc_only t) tll
- else if etll then rtime "Tree.first_child" (Tree.first_child) t
- else (* add child only *)
- rtime "Tree.tagged_below" (Tree.tagged_below t tl) tll
- and next =
- if Ptset.mem Tag.pcdata (pt_cup tr trr)
- then
- rtime "Tree.text_next" (Tree.text_next t) ctx
- else
- let etr = Ptset.is_empty tr
- and etrr = Ptset.is_empty trr
- in
- if etr && etrr
- then Tree.mk_nil t
- else
- if etr then rtime "Tree.tagged_foll_only" (Tree.tagged_foll_only t trr) ctx
- else if etrr then rtime "Tree.next_sibling" (Tree.next_sibling) t
- else (* add ns only *)
- rtime "Tree.tagged_next" (Tree.tagged_next t tr trr) ctx
-
+ | Not_found ->
+ let fl_list,llist,rlist,ca,da,sa,fa =
+ SList.fold
+ (fun set (fll_acc,lllacc,rllacc,ca,da,sa,fa) -> (* For each set *)
+ let fl,ll,rr,ca,da,sa,fa =
+ StateSet.fold
+ (fun q acc ->
+ List.fold_left
+ (fun ((fl_acc,ll_acc,rl_acc,c_acc,d_acc,s_acc,f_acc) as acc)
+ (ts,t) ->
+ if (TagSet.mem tag ts)
+ then
+ let _,_,f,_ = Transition.node t in
+ let (child,desc,below),(sibl,foll,after) = Formula.st f in
+ (Formlist.cons t fl_acc,
+ StateSet.union ll_acc below,
+ StateSet.union rl_acc after,
+ StateSet.union child c_acc,
+ StateSet.union desc d_acc,
+ StateSet.union sibl s_acc,
+ StateSet.union foll f_acc)
+ else acc ) acc (
+ try Hashtbl.find a.trans q
+ with
+ Not_found -> Printf.eprintf "Looking for state %i, doesn't exist!!!\n%!"
+ q;[]
+ )
+
+ ) set (Formlist.nil,StateSet.empty,StateSet.empty,ca,da,sa,fa)
+ in fl::fll_acc, (SList.cons ll lllacc), (SList.cons rr rllacc),ca,da,sa,fa)
+ slist ([],SList.nil,SList.nil,StateSet.empty,StateSet.empty,StateSet.empty,StateSet.empty)
in
- let s1,res1 = accepting_among_time a first (pt_cup ls lls) t
- and s2,res2 = accepting_among_time a next (pt_cup rs rrs) ctx
- in
- let rb,rb1,rb2 = rtime "eval_form_bool" (eval_form_bool formula s1) s2 in
- if rb
- then
- let res1 = if rb1 then res1 else TS.empty
- and res2 = if rb2 then res2 else TS.empty
- in r', rtime "TS.concat" (TS.concat res2) (if mark then rtime "TS.append" (TS.append t) res1 else res1),formula
- else Ptset.empty,TS.empty,formula
-
- in
+ (* Logic to chose the first and next function *)
+ let tags_below,tags_after = Tree.tags t tag in
+ let first = choose_jump_down tags_below ca da a
+ and next = choose_jump_next tags_after sa fa a in
+ let v = (fl_list,llist,rlist,first,next) in
+ Hashtbl.add td_trans (tag, SList.hash slist) v; v
+
+ let merge rb rb1 rb2 mark t res1 res2 =
+ if rb
+ then
+ let res1 = if rb1 then res1 else RS.empty
+ and res2 = if rb2 then res2 else RS.empty
+ in
+ if mark then RS.cons t (RS.concat res1 res2)
+ else RS.concat res1 res2
+ else RS.empty
- among,result
-
- else orig,TS.empty
-
-
- let run_time a t =
- let st,res = accepting_among_time a t a.init t in
- let _ = Printf.eprintf "\n Timings\n";
- let total_time = Hashtbl.fold (fun fname ({ contents=cpt }, {contents=atime}) (total_time) ->
- Printf.eprintf "%s\t %i calls, %f ms accumulated time, %f ms mean time\n"
- fname cpt atime (atime /. (float_of_int cpt));
- total_time +. atime ) h_time 0.
+ let empty_size n =
+ let rec loop acc = function 0 -> acc
+ | n -> loop (SList.cons StateSet.empty acc) (n-1)
+ in loop SList.nil n
+
+ let top_down ?(noright=false) a t slist ctx slot_size =
+ let pempty = empty_size slot_size in
+ let eval_fold2_slist fll sl1 sl2 res1 res2 t =
+ let res = Array.copy res1 in
+ let rec fold l1 l2 fll i aq =
+ match SList.node l1,SList.node l2, fll with
+ | SList.Cons(s1,ll1),
+ SList.Cons(s2,ll2),
+ fl::fll ->
+ let r',rb,rb1,rb2,mark = eval_formlist s1 s2 fl in
+ let _ = res.(i) <- merge rb rb1 rb2 mark t res1.(i) res2.(i)
+ in
+ fold ll1 ll2 fll (i+1) (SList.cons r' aq)
+ | SList.Nil, SList.Nil,[] -> aq,res
+ | _ -> assert false
+ in
+ fold sl1 sl2 fll 0 SList.nil
in
- Printf.eprintf "total calls %i, total monitored time %f ms\n%!" !calls total_time
- in
- if Ptset.is_empty (st) then TS.empty else res
-
-
-
- let rec accepting_among a t r ctx =
- let orig = r in
- let rest = Ptset.inter r a.final in
- let r = Ptset.diff r rest in
- if Ptset.is_empty r then rest,TS.empty else
- if Tree.is_node t
- then
- let among,result,form =
- let ((ls,lls),(rs,rrs)),formula,mark,has_true,r' =
- let tag = Tree.tag t in
- get_trans t a tag r
- in
- let tl = tags a ls
- and tr = tags a rs
- and tll = tags a lls
- and trr = tags a rrs
- in
- let first =
- if Ptset.mem Tag.pcdata (pt_cup tl tll)
- then
- Tree.text_below t
- else
- let etl = Ptset.is_empty tl
- and etll = Ptset.is_empty tll
- in
- if etl && etll
- then Tree.mk_nil t
- else
- if etl then Tree.tagged_desc_only t tll
- else if etll then Tree.first_child t
- else (* add child only *)
- Tree.tagged_below t tl tll
- and next =
- if Ptset.mem Tag.pcdata (pt_cup tr trr)
- then
- Tree.text_next t ctx
- else
- let etr = Ptset.is_empty tr
- and etrr = Ptset.is_empty trr
- in
- if etr && etrr
- then Tree.mk_nil t
- else
- if etr then Tree.tagged_foll_only t trr ctx
- else if etrr then Tree.next_sibling t
- else (* add ns only *)
- Tree.tagged_next t tr trr ctx
-
- in
- let s1,res1 = accepting_among a first (pt_cup ls lls) t
- and s2,res2 = accepting_among a next (pt_cup rs rrs) ctx
- in
- let rb,rb1,rb2 = eval_form_bool formula s1 s2 in
- if rb
- then
- let res1 = if rb1 then res1 else TS.empty
- and res2 = if rb2 then res2 else TS.empty
- in r', TS.concat res2 (if mark then TS.append t res1 else res1),formula
- else Ptset.empty,TS.empty,formula
-
- in
- among,result
-
- else orig,TS.empty
+ let null_result() = (pempty,Array.make slot_size RS.empty) in
+ let rec loop t slist ctx =
+ if Tree.is_nil t then null_result()
+ else
+ let tag = Tree.tag t in
+ let fl_list,llist,rlist,first,next = get_trans slist tag a t in
+ let sl1,res1 = loop (first t) llist t in
+ let sl2,res2 = loop (next t ctx) rlist ctx in
+ let res = eval_fold2_slist fl_list sl1 sl2 res1 res2 t
+ in
+ D_IGNORE_(
+ register_trace t (slist,(fst res),sl1,sl2,fl_list,first,next,ctx),
+ res)
+ in
+ let loop_no_right t slist ctx =
+ if Tree.is_nil t then null_result()
+ else
+ let tag = Tree.tag t in
+ let fl_list,llist,_,first,next = get_trans slist tag a t in
+ let sl1,res1 = loop (first t) llist t in
+ let sl2,res2 = null_result() in
+ let res = eval_fold2_slist fl_list sl1 sl2 res1 res2 t
+ in
+ D_IGNORE_(
+ register_trace t (slist,(fst res),sl1,sl2,fl_list,first,next,ctx),
+ res)
+ in
+ (if noright then loop_no_right else loop) t slist ctx
+
-
- let run a t =
- let st,res = accepting_among a t a.init t in
- if Ptset.is_empty (st) then TS.empty else res
-
- let rec accepting_among_count a t r ctx =
- let orig = r in
- let rest = Ptset.inter r a.final in
- let r = Ptset.diff r rest in
- if Ptset.is_empty r then rest,0 else
- if Tree.is_node t
- then
- let ((ls,lls),(rs,rrs)),formula,mark,has_true,r' =
- let tag = Tree.tag t in
- get_trans t a tag r
- in
- let tl = tags a ls
- and tr = tags a rs
- and tll = tags a lls
- and trr = tags a rrs
- in
- let first =
- if Ptset.mem Tag.pcdata (pt_cup tl tll)
- then
- Tree.text_below t
- else
- let etl = Ptset.is_empty tl
- and etll = Ptset.is_empty tll
- in
- if etl && etll
- then Tree.mk_nil t
- else
- if etl then Tree.tagged_desc_only t tll
- else if etll then Tree.first_child t
- else (* add child only *)
- Tree.tagged_below t tl tll
- and next =
- if Ptset.mem Tag.pcdata (pt_cup tr trr)
- then
- Tree.text_next t ctx
- else
- let etr = Ptset.is_empty tr
- and etrr = Ptset.is_empty trr
- in
- if etr && etrr
- then Tree.mk_nil t
- else
- if etr then Tree.tagged_foll_only t trr ctx
- else if etrr then Tree.next_sibling t
- else (* add ns only *)
- Tree.tagged_next t tr trr ctx
-
+ let run_top_down a t =
+ let init = SList.cons a.init SList.nil in
+ let _,res = top_down a t init t 1
+ in
+ D_IGNORE_(
+ output_trace a t "trace.html"
+ (RS.fold (fun t a -> IntSet.add (Tree.id t) a) res.(0) IntSet.empty),
+ res.(0))
+ ;;
+
+ module Configuration =
+ struct
+ module Ptss = Set.Make(StateSet)
+ module IMap = Map.Make(StateSet)
+ type t = { hash : int;
+ sets : Ptss.t;
+ results : RS.t IMap.t }
+ let empty = { hash = 0;
+ sets = Ptss.empty;
+ results = IMap.empty;
+ }
+ let is_empty c = Ptss.is_empty c.sets
+ let add c s r =
+ if Ptss.mem s c.sets then
+ { c with results = IMap.add s (RS.concat r (IMap.find s c.results)) c.results}
+ else
+ { hash = HASHINT2(c.hash,Ptset.Int.uid s);
+ sets = Ptss.add s c.sets;
+ results = IMap.add s r c.results
+ }
+
+ let pr fmt c = Format.fprintf fmt "{";
+ Ptss.iter (fun s -> StateSet.print fmt s;
+ Format.fprintf fmt " ") c.sets;
+ Format.fprintf fmt "}\n%!";
+ IMap.iter (fun k d ->
+ StateSet.print fmt k;
+ Format.fprintf fmt "-> %i\n" (RS.length d)) c.results;
+ Format.fprintf fmt "\n%!"
+
+ let merge c1 c2 =
+ let acc1 = IMap.fold (fun s r acc ->
+ IMap.add s
+ (try
+ RS.concat r (IMap.find s acc)
+ with
+ | Not_found -> r) acc) c1.results IMap.empty
in
- let s1,res1 = accepting_among_count a first (pt_cup ls lls) t
- and s2,res2 = accepting_among_count a next (pt_cup rs rrs) ctx
+ let imap =
+ IMap.fold (fun s r acc ->
+ IMap.add s
+ (try
+ RS.concat r (IMap.find s acc)
+ with
+ | Not_found -> r) acc) c2.results acc1
in
- let rb,rb1,rb2 = eval_form_bool formula s1 s2 in
- if rb
- then
- let res1 = if rb1 then res1 else 0
- and res2 = if rb2 then res2 else 0
- in r', res2 + (if mark then 1 + res1 else res1)
- else Ptset.empty,0
-
-
+ let h,s =
+ Ptss.fold
+ (fun s (ah,ass) -> (HASHINT2(ah,Ptset.Int.uid s),
+ Ptss.add s ass))
+ (Ptss.union c1.sets c2.sets) (0,Ptss.empty)
+ in
+ { hash = h;
+ sets =s;
+ results = imap }
+
+ end
+
+ let h_fold = Hashtbl.create 511
+
+ let fold_f_conf t slist fl_list conf dir=
+ let rec loop sl fl acc =
+ match SList.node sl,fl with
+ |SList.Nil,[] -> acc
+ |SList.Cons(s,sll), formlist::fll ->
+ let r',rb,rb1,rb2,mark =
+ let key = SList.hash sl,Formlist.hash formlist,dir in
+ try
+ Hashtbl.find h_fold key
+ with
+ Not_found -> let res =
+ if dir then eval_formlist s Ptset.Int.empty formlist
+ else eval_formlist Ptset.Int.empty s formlist
+ in (Hashtbl.add h_fold key res;res)
+ in
+ if rb && ((dir&&rb1)|| ((not dir) && rb2))
+ then
+ let acc =
+ let old_r =
+ try Configuration.IMap.find s conf.Configuration.results
+ with Not_found -> RS.empty
+ in
+ Configuration.add acc r' (if mark then RS.cons t old_r else old_r)
+ in
+ loop sll fll acc
+ else loop sll fll acc
+ | _ -> assert false
+ in
+ loop slist fl_list Configuration.empty
+
+ let h_trans = Hashtbl.create 4096
+
+ let get_up_trans slist ptag a tree =
+ let key = (HASHINT2(SList.uid slist,ptag)) in
+ try
+ Hashtbl.find h_trans key
+ with
+ | Not_found ->
+ let f_list =
+ Hashtbl.fold (fun q l acc ->
+ List.fold_left (fun fl_acc (ts,t) ->
+ if TagSet.mem ptag ts then Formlist.cons t fl_acc
+ else fl_acc)
+
+ acc l)
+ a.trans Formlist.nil
+ in
+ let res = SList.fold (fun _ acc -> f_list::acc) slist []
+ in
+ (Hashtbl.add h_trans key res;res)
- else orig,0
+
+ let h_tdconf = Hashtbl.create 511
+ let rec bottom_up a tree conf next jump_fun root dotd init accu =
+ if (not dotd) && (Configuration.is_empty conf ) then
-
- let run_count a t =
- let st,res = accepting_among_count a t a.init t in
- if Ptset.is_empty (st) then 0 else res
+ accu,conf,next
+ else
+ let below_right = Tree.is_below_right tree next in
+ let accu,rightconf,next_of_next =
+ if below_right then (* jump to the next *)
+ bottom_up a next conf (jump_fun next) jump_fun (Tree.next_sibling tree) true init accu
+ else accu,Configuration.empty,next
+ in
+ let sub =
+ if dotd then
+ if below_right then prepare_topdown a tree true
+ else prepare_topdown a tree false
+ else conf
+ in
+ let conf,next =
+ (Configuration.merge rightconf sub, next_of_next)
+ in
+ if Tree.equal tree root then accu,conf,next
+ else
+ let parent = Tree.binary_parent tree in
+ let ptag = Tree.tag parent in
+ let dir = Tree.is_left tree in
+ let slist = Configuration.Ptss.fold (fun e a -> SList.cons e a) conf.Configuration.sets SList.nil in
+ let fl_list = get_up_trans slist ptag a parent in
+ let slist = SList.rev (slist) in
+ let newconf = fold_f_conf parent slist fl_list conf dir in
+ let accu,newconf = Configuration.IMap.fold (fun s res (ar,nc) ->
+ if Ptset.Int.intersect s init then
+ ( RS.concat res ar ,nc)
+ else (ar,Configuration.add nc s res))
+ (newconf.Configuration.results) (accu,Configuration.empty)
+ in
+ bottom_up a parent newconf next jump_fun root false init accu
+
+ and prepare_topdown a t noright =
+ let tag = Tree.tag t in
+(* pr "Going top down on tree with tag %s = %s "
+ (if Tree.is_nil t then "###" else (Tag.to_string(Tree.tag t))) (Tree.dump_node t); *)
+ let r =
+ try
+ Hashtbl.find h_tdconf tag
+ with
+ | Not_found ->
+ let res = Hashtbl.fold (fun q l acc ->
+ if List.exists (fun (ts,_) -> TagSet.mem tag ts) l
+ then Ptset.Int.add q acc
+ else acc) a.trans Ptset.Int.empty
+ in Hashtbl.add h_tdconf tag res;res
+ in
+(* let _ = pr ", among ";
+ StateSet.print fmt (Ptset.Int.elements r);
+ pr "\n%!";
+ in *)
+ let r = SList.cons r SList.nil in
+ let set,res = top_down (~noright:noright) a t r t 1 in
+ let set = match SList.node set with
+ | SList.Cons(x,_) ->x
+ | _ -> assert false
+ in
+(* pr "Result of topdown run is %!";
+ StateSet.print fmt (Ptset.Int.elements set);
+ pr ", number is %i\n%!" (RS.length res.(0)); *)
+ Configuration.add Configuration.empty set res.(0)
+
+
+
+ let run_bottom_up a t k =
+ let trlist = Hashtbl.find a.trans (Ptset.Int.choose a.init)
+ in
+ let init = List.fold_left
+ (fun acc (_,t) ->
+ let _,_,f,_ = Transition.node t in
+ let _,_,l = fst ( Formula.st f ) in
+ Ptset.Int.union acc l)
+ Ptset.Int.empty trlist
+ in
+ let tree1,jump_fun =
+ match k with
+ | `TAG (tag) ->
+ (*Tree.tagged_lowest t tag, fun tree -> Tree.tagged_next tree tag*)
+ (Tree.tagged_desc tag t, fun tree -> Tree.tagged_foll_ctx tag tree t)
+ | `CONTAINS(_) -> (Tree.text_below t,fun tree -> Tree.text_next tree t)
+ | _ -> assert false
+ in
+ let tree2 = jump_fun tree1 in
+ let rec loop tree next acc =
+(* let _ = pr "\n_________________________\nNew iteration\n" in
+ let _ = pr "Jumping to %s\n%!" (Tree.dump_node tree) in *)
+ let acc,conf,next_of_next = bottom_up a tree
+ Configuration.empty next jump_fun (Tree.root tree) true init acc
+ in
+ (* let _ = pr "End of first iteration, conf is:\n%!";
+ Configuration.pr fmt conf
+ in *)
+ let acc = Configuration.IMap.fold
+ ( fun s res acc -> if Ptset.Int.intersect init s
+ then RS.concat res acc else acc) conf.Configuration.results acc
+ in
+ if Tree.is_nil next_of_next (*|| Tree.equal next next_of_next *)then
+ acc
+ else loop next_of_next (jump_fun next_of_next) acc
+ in
+ loop tree1 tree2 RS.empty
+
+
+ end
+
+ let top_down_count a t = let module RI = Run(Integer) in Integer.length (RI.run_top_down a t)
+ let top_down a t = let module RI = Run(IdSet) in (RI.run_top_down a t)
+ let bottom_up_count a t k = let module RI = Run(Integer) in Integer.length (RI.run_bottom_up a t k)
-(*
- end
-*)