| False | True
| Or of formula * formula
| And of formula * formula
- | Atom of ([ `Left | `Right ]*bool*state)
+ | Atom of ([ `Left | `Right | `LLeft | `RRight ]*bool*state)
and formula = { fid: int;
+ fkey : int;
pos : formula_expr;
neg : formula;
- st : Ptset.t*Ptset.t;
+ 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
+
module FormNode =
struct
type t = formula
- let hash = function
- | False -> 0
- | True -> 1
- | And(f1,f2) -> 2+17*f1.fid + 37*f2.fid
- | Or(f1,f2) -> 3+101*f1.fid + 253*f2.fid
- | Atom(d,b,s) -> 5+(if d=`Left then 11 else 19)*(if b then 23 else 31)*s
-
- let hash t = (hash t.pos) land max_int
-
+
+ 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 (d1 = d2) && (b1=b2) &&(s1=s2) -> 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
+
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; neg = f ; st = Ptset.empty,Ptset.empty; size =1; }
- and f = { fid = 0; pos = False; neg = t; st = Ptset.empty,Ptset.empty; size = 1; }
+ 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;
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;
and nnode = {
fid = gen_id ();
pos = neg;
+ fkey = hash_node_form neg;
neg = pnode;
st = s2;
size = size2;
let atom_ d p s =
let si = Ptset.singleton s in
let ss = match d with
- | `Left -> si,Ptset.empty
- | `Right -> Ptset.empty,si
+ | `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 =
- Ptset.union (fst f1.st) (fst f2.st),
- Ptset.union (snd f1.st) (snd f2.st)
+ union_quad f1.st f2.st
and sn =
- Ptset.union (fst f1.neg.st) (fst f2.neg.st),
- Ptset.union (snd f1.neg.st) (snd f2.neg.st)
+ union_quad f1.neg.st f2.neg.st
in
sp,sn
-
+
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
struct
type t = Ptset.t*Tag.t
let int_hash key = key lsl 31 lor (key lsl 8)
- let equal (s1,s2) (t1,t2) = Tag.equal s2 t2 && Ptset.equal s1 t1
+ 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))
end
module HTagSet = Hashtbl.Make(HTagSetKey)
(pr_frm ppf f2);
| Atom(dir,b,s) -> Format.fprintf ppf "%s%s[%i]"
(if b then "" else "¬")
- (if dir = `Left then "↓₁" else "↓₂") s
+ (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,_,s) -> PL.singleton (Ptset.singleton s,Ptset.empty)
- | Atom(`Right,_,s) -> PL.singleton (Ptset.empty,Ptset.singleton s)
+ | 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
+ 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
+ Not_found ->
+ let d = dnf_aux f in
+ Hashtbl.add dnf_hash f.fid d;d
- let can_top_down f =
+ 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
+ | [(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 =
let s =
if TagSet.is_finite ts
- then "{" ^ (TagSet.fold (fun t a -> a ^ " " ^ (Tag.to_string t)) 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 "*\\{"
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,r = f.st in pr_st ppf (Ptset.elements l);
+ 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 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
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 e t = concat t (cons e empty)
+ 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 =
| Concat(n1,n2) -> let _ = loop n1 in loop n2
in loop n
- end
- module TS2 =
- struct
- type t = string
- let empty = String.make 10_000_000 '0'
- let cons e t = t.[Tree.id e] <- '1';t
- let append = cons
- let concat s1 s2 = failwith "not implemented"
-
- let length t =
- let res = ref 0 in
- for i = 0 to 9_999_999 do
- if t.[i] == '1' then
- incr res
- done; !res
-
- let iter f t = failwith "not implemented"
- let to_list_rev t = failwith "not implemented"
- end
+ 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
- module BottomUpNew = struct
-
-IFDEF DEBUG
-THEN
- type trace =
- | TNil of Ptset.t*Ptset.t
- | TNode of Ptset.t*Ptset.t*bool* (int*bool*formula) list
-
- let traces = Hashtbl.create 17
- let dump_trace t =
- let out = open_out "debug_trace.dot"
- in
- let outf = Format.formatter_of_out_channel out in
-
- let rec aux t num =
- if Tree.is_node t
- then
- match (try Hashtbl.find traces (Tree.id t) with Not_found -> TNil(Ptset.empty,Ptset.empty)) with
- | TNode(r,s,mark,trs) ->
- let numl = aux (Tree.left t) num in
- let numr = aux (Tree.right t) (numl+1) in
- let mynum = numr + 1 in
- Format.fprintf outf "n%i [ label=\"<%s>\\nr=" mynum (Tag.to_string (Tree.tag t));
- pr_st outf (Ptset.elements r);
- Format.fprintf outf "\\ns=";
- pr_st outf (Ptset.elements s);
- List.iter (fun (q,m,f) ->
- Format.fprintf outf "\\n%i %s" q (if m then "⇨" else "→");
- pr_frm outf f ) trs;
- Format.fprintf outf "\", %s shape=box ];\n"
- (if mark then "color=cyan1, style=filled," else "");
- let _ = Format.fprintf outf "n%i -> n%i;\n" mynum numl in
- let _ = Format.fprintf outf "n%i -> n%i;\n" mynum numr in
- mynum
- | TNil(r,s) -> Format.fprintf outf "n%i [ shape=box, label=\"Nil\\nr=" num;
- pr_st outf (Ptset.elements r);
- Format.fprintf outf "\\ns=";
- pr_st outf (Ptset.elements s);
- Format.fprintf outf "\"];\n";num
- else
- match Hashtbl.find traces (-10) with
- | TNil(r,s) ->
- Format.fprintf outf "n%i [ shape=box, label=\"Nil\\nr=" num;
- pr_st outf (Ptset.elements r);
- Format.fprintf outf "\\ns=";
- pr_st outf (Ptset.elements s);
- Format.fprintf outf "\"];\n";
- num
- | _ -> assert false
+ 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
- Format.fprintf outf "digraph G {\n";
- ignore(aux t 0);
- Format.fprintf outf "}\n%!";
- close_out out;
- ignore(Sys.command "dot -Tsvg debug_trace.dot > debug_trace.svg")
-END
-
+ loop n
+ end
+(*
+ module BottomUpJumpNew = struct
+*)
module HFEval = Hashtbl.Make(
struct
type t = int*Ptset.t*Ptset.t
let hash (a,b,c) =
a+17*(Ptset.hash b) + 31*(Ptset.hash c)
end)
-
+
let hfeval = HFEval.create 4097
-(* let miss = ref 0
- let call = ref 0
- let timeref = ref 0.0
- let timerefall = ref 0.0
- let time f x =
- incr call;
- let t1 = Unix.gettimeofday ()
- in let r = f x
- in
- timeref := !timeref +. ((Unix.gettimeofday()) -. t1);
- r
-
- let timeall f x =
- let t1 = Unix.gettimeofday ()
- in let r = f x
- in
- timerefall := !timerefall +. ((Unix.gettimeofday()) -. t1);
- r
-
-*)
-
-
let eval_form_bool f s1 s2 =
let rec eval f = match f.pos with
- | Atom(`Left,b,q) -> if b == (Ptset.mem q s1) then (true,true,false) else false,false,false
- | Atom(`Right,b,q) -> if b == (Ptset.mem q s2) then (true,false,true) else false,false,false
+ | 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
in eval f
- module HFEvalDir = Hashtbl.Make(
- struct
- type t = int*Ptset.t*[`Left | `Right ]
- let equal (a,b,c) (d,e,f) =
- a==d && (Ptset.equal b e) && (c = f)
- let hash_dir = function `Left -> 7919
- | `Right -> 3517
-
- let hash (a,b,c) =
- a+17*(Ptset.hash b) + 31*(hash_dir c)
- end)
-
- let hfeval_dir = HFEvalDir.create 4097
-
-
- let eval_dir dir f s =
- let rec eval f = match f.pos with
- | Atom(d,b,q) when d = dir -> if b == (Ptset.mem q s) then true_ else false_
- | Atom(_,b,q) -> f
- (* test some inlining *)
- | True -> true_
- | False -> false_
- | _ ->
- try
- HFEvalDir.find hfeval_dir (f.fid,s,dir)
- with
- | Not_found ->
- let r =
- match f.pos with
- | Or(f1,f2) ->
- let f1 = eval f1
- in
- if is_true f1 then true_
- else if is_false f1 then eval f2
- else or_ f1 f2
- | And(f1,f2) ->
- let f1 = eval f1 in
- if is_false f1 then false_
- else if is_true f1 then eval f2
- else and_ f1 f2
- | _ -> assert false
- in
- HFEvalDir.add hfeval_dir (f.fid,s,dir) r;
- r
-
- in eval f
-
-
-
let fstate_pool = Hashtbl.create 11
let merge_pred a b = match a,b with
else f,false in
(or_ tmpf accf,accm||m,acchtrue||hastrue)
else (accf,accm,acchtrue)
- ) acc (Hashtbl.find a.phi q)
-
+ ) acc (try Hashtbl.find a.phi q with Not_found -> [])
let get_trans t a tag r =
try
HTagSet.add a.sigma (accq,tag) (mark,f,([],[]),has_true);
f.st,f,mark,has_true,accq
+ let h_union = Hashtbl.create 4097
+
+ 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
+
+
+
+ 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
+
+
- let check_pred l t = true (*l = [] ||
- List.exists (function p ->
- match p with
- `Left f | `Right f -> f t
- | _ -> assert false) l
- *)
+
+ 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 rec accepting_among2 a t r acc =
+ let rtime s f x =
+
+ let cpt,atime =
+ try
+ Hashtbl.find h_time s
+ 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,acc else
- if (not (Tree.is_node t))
+ if Ptset.is_empty r then rest,TS.empty else
+ if Tree.is_node t
then
- orig,acc
- else
- let t1 = Tree.first_child t
- and t2 = Tree.next_sibling t in
- let (r1,r2),formula,mark,has_true,r = get_trans t a (Tree.tag t) r
- in
- let s1,res1 = accepting_among2 a t1 r1 acc
- in
- let formula = eval_dir `Left formula s1 in
- if is_false formula then rest,acc
- else
- if is_true formula then (* tail call equivalent to a top down *)
- accepting_among2 a t2 orig (if mark then TS.append t res1 else res1)
+ 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 s2,res2 = accepting_among2 a t2 r2 res1
+ let etl = Ptset.is_empty tl
+ and etll = Ptset.is_empty tll
in
- let formula = eval_dir `Right formula s2
+ 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 is_false formula then rest,res1
+ if etr && etrr
+ then Tree.mk_nil t
else
- orig,(if mark then TS.append t (res2)
- else res2)
+ 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
+
+ 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
+
+ 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.
+ 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 =
+
+
+ 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 (r1,r2),formula,mark,has_true,r = get_trans t a (Tree.tag t) r
- in
- let s1,res1 = accepting_among a (Tree.first_child t) r1
- and s2,res2 = accepting_among a (Tree.next_sibling t) r2
- 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.cons t res1 else res1)
- else orig,TS.empty
+ 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 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_count a t r =
- 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 (r1,r2),formula,mark,has_true,r = get_trans t a (Tree.tag t) r
- in
- let s1,res1 = accepting_count a (Tree.first_child t) r1
- and s2,res2 = accepting_count a (Tree.next_sibling t) r2
- 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, res1+res2+(if mark then 1 else 0)
- else orig,0
- else orig,0
-
- let run a t =
-(* let _ =
- call := 0; miss:=0;
- timeref := 0.0;
- HFEval.clear hfeval;
- Hashtbl.clear dnf_hash;
- Hashtbl.clear fstate_pool;
- in *)
- let st,res = accepting_among a t a.init in
- let b = Ptset.is_empty (st) in
- if b then TS.empty
- else
- res
-
- let run_count a t =
-(* let _ =
- call := 0; miss:=0;
- timeref := 0.0;
- timerefall := 0.0;
- HFEval.clear hfeval;
- Hashtbl.clear dnf_hash;
- Hashtbl.clear fstate_pool;
- in *)
- let st,res = accepting_count a t a.init in
- let b = Ptset.is_empty (st) in
- if b then 0
- else
- res
- end
-
- module Jump = struct
- let eval_dir = BottomUpNew.eval_dir
- let xi1 = HTagSet.create 10
- let xi2 = HTagSet.create 10
-
- let rec accept_from orig a t r acc =
- if (Tree.is_root t) ||
- (Ptset.subset orig r)
- then
- acc
- else
- let is_left = Tree.is_left t in
- let tag = Tree.tag t in
- let nr,f, mark =
- try
- HTagSet.find (if is_left then xi1 else xi2)
- (r,tag)
- with
- | Not_found ->
- let trans =
- Hashtbl.fold
- (fun q l acc ->
- List.fold_left (fun ((racc,facc,macc) as acc) (ts,(m,f,_)) ->
- let rl,rr = f.st in
- if (TagSet.mem tag ts) &&
- (Ptset.intersect (if is_left then rl else rr) r)
- then (Ptset.add q racc,or_ f facc, macc||m)
- else acc) acc l)
- a.phi (Ptset.empty,false_,false)
- in
- HTagSet.add (if is_left then xi1 else xi2) (r,tag) trans;
- trans
- in
- let form = eval_dir (if is_left then `Left else `Right) f r
- in
- if is_true form then accept_from orig a (Tree.parent t) nr
- (if mark then TS.cons t acc else acc)
- else if is_false form then TS.empty
- else assert false
-
- let run a t r =
- HTagSet.clear xi1;
- HTagSet.clear xi2;
- let orig =
- List.fold_left (fun s (_,(_,f,_)) ->
- Ptset.union s (fst f.st))
- Ptset.empty (Hashtbl.find a.phi (Ptset.choose a.init))
- in
- accept_from orig a t r TS.empty
-
+(*
end
+*)