end =
struct
type t = int
- let make = let id = ref ~-1 in
- fun () -> incr id; !id
+ let make =
+ let id = ref ~-1 in
+ fun () -> incr id; !id
let compare = (-)
let equal = (==)
if x < 0 then failwith (Printf.sprintf "State: Assertion %i < 0 failed" x)
end
-module StateSet = Ptset.Int
-
+module StateSet =
+struct
+ include Ptset.Make ( struct type t = int
+ type data = t
+ external hash : t -> int = "%identity"
+ external uid : t -> Uid.t = "%identity"
+ external equal : t -> t -> bool = "%eq"
+ external make : t -> int = "%identity"
+ external node : t -> int = "%identity"
+ external with_id : Uid.t -> t = "%identity"
+ end
+ )
+ 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
+
module Formula =
struct
type 'hcons expr =
end
-module TransTable = Hashtbl
-
module Formlist = struct
include Hlist.Make(Transition)
let print ppf fl =
type 'a t = {
id : int;
- mutable states : Ptset.Int.t;
- init : Ptset.Int.t;
- starstate : Ptset.Int.t option;
+ mutable states : StateSet.t;
+ init : StateSet.t;
+ starstate : StateSet.t option;
(* Transitions of the Alternating automaton *)
trans : (State.t,(TagSet.t*Transition.t) list) Hashtbl.t;
query_string: string;
val merge : merge_conf -> elt -> t -> t -> t
val mk_quick_tag_loop : (elt -> elt -> 'a*t array) -> 'a -> int -> Tree.t -> Tag.t -> (elt -> elt -> 'a*t array)
val mk_quick_star_loop : (elt -> elt -> 'a*t array) -> 'a -> int -> Tree.t -> (elt -> elt -> 'a*t array)
+
end
module Integer : ResultSet =
else 0
let merge conf t res1 res2 =
match conf with
- NO -> 0
+ | NO -> 0
| ONLY1 -> res1
| ONLY2 -> res2
| ONLY12 -> res1+res2
| MARK1 -> res1+1
| MARK2 -> res2+1
| MARK12 -> res1+res2+1
+ let merge conf _ res1 res2 =
+ let conf = Obj.magic conf in
+ (conf lsr 2) + ((conf land 0b10) lsr 1)*res2 + (conf land 0b1)*res1
+
let mk_quick_tag_loop _ sl ss tree tag = ();
fun t ctx ->
let mk_quick_star_loop _ sl ss tree = ();
fun t ctx ->
(sl, Array.make ss (Tree.subtree_elements tree t))
-
+
end
module IdSet : ResultSet=
INCLUDE "html_trace.ml"
END
- 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 mk_app_fun f arg _ = f arg
- let mk_app_fun2 f arg1 arg2 s = let g = f arg1 arg2 in
- D_IGNORE_(register_funname g ((get_funname f) ^ " " ^ s), g)
-(* let mk_app_fun2 f arg1 arg2 s = Printf.eprintf "Building f2 %s\n%!" s; f arg1 arg2 *)
+ module Trace =
+ struct
+ module HFname = Hashtbl.Make (struct
+ type t = Obj.t
+ let hash = Hashtbl.hash
+ let equal = (==)
+ end)
+
+ let h_fname = HFname.create 401
+
+ let register_funname f s =
+ HFname.add h_fname (Obj.repr f) s
+ let get_funname f = try HFname.find h_fname (Obj.repr f) with _ -> "[anon_fun]"
+
+
+
+ let mk_fun f s = register_funname f s;f
+ let mk_app_fun f arg s =
+ let g = f arg in
+ register_funname g ((get_funname f) ^ " " ^ s); g
+ let mk_app_fun2 f arg1 arg2 s =
+ let g = f arg1 arg2 in
+ register_funname g ((get_funname f) ^ " " ^ s); g
+
+ end
let string_of_ts tags = (Ptset.Int.fold (fun t a -> a ^ " " ^ (Tag.to_string t) ) tags "{")^ " }"
if Ptset.Int.is_empty cl then
if Ptset.Int.is_singleton ll then
let tag = Ptset.Int.choose ll in
- (`TAG(tag),mk_app_fun f_tn tag (Tag.to_string tag))
+ (`TAG(tag),Trace.mk_app_fun f_tn tag (Tag.to_string tag))
else
- (`MANY(ll),mk_app_fun f_sn ll (string_of_ts ll))
+ (`MANY(ll),Trace.mk_app_fun f_sn ll (string_of_ts ll))
else if Ptset.Int.is_empty ll then
if Ptset.Int.is_singleton cl then
let tag = Ptset.Int.choose cl in
- (`TAG(tag),mk_app_fun f_t1 tag (Tag.to_string tag))
+ (`TAG(tag),Trace.mk_app_fun f_t1 tag (Tag.to_string tag))
else
- (`MANY(cl),mk_app_fun f_s1 cl (string_of_ts cl))
+ (`MANY(cl),Trace.mk_app_fun f_s1 cl (string_of_ts cl))
else
- (`ANY,mk_app_fun2 f_s1n cl ll ((string_of_ts cl) ^ " " ^ (string_of_ts ll)))
+ (`ANY,Trace.mk_app_fun2 f_s1n cl ll ((string_of_ts cl) ^ " " ^ (string_of_ts ll)))
| _ -> assert false
let choose_jump_down tree d =
choose_jump d
- (mk_fun (fun _ -> Tree.nil) "Tree.mk_nil")
- (mk_fun (Tree.tagged_child tree) "Tree.tagged_child")
- (mk_fun (Tree.select_child tree) "Tree.select_child")
- (mk_fun (Tree.tagged_descendant tree) "Tree.tagged_desc")
- (mk_fun (Tree.select_descendant tree) "Tree.select_desc")
- (mk_fun (fun _ _ -> Tree.first_child tree) "[FIRSTCHILD]Tree.select_child_desc")
- (mk_fun (Tree.first_element tree) "Tree.first_element")
- (mk_fun (Tree.first_child tree) "Tree.first_child")
+ (Trace.mk_fun (fun _ -> Tree.nil) "Tree.mk_nil")
+ (Trace.mk_fun (Tree.tagged_child tree) "Tree.tagged_child")
+ (Trace.mk_fun (Tree.select_child tree) "Tree.select_child")
+ (Trace.mk_fun (Tree.tagged_descendant tree) "Tree.tagged_desc")
+ (Trace.mk_fun (Tree.select_descendant tree) "Tree.select_desc")
+ (Trace.mk_fun (fun _ _ -> Tree.first_child tree) "[FIRSTCHILD]Tree.select_child_desc")
+ (Trace.mk_fun (Tree.first_element tree) "Tree.first_element")
+ (Trace.mk_fun (Tree.first_child tree) "Tree.first_child")
let choose_jump_next tree d =
choose_jump d
- (mk_fun (fun _ _ -> Tree.nil) "Tree.mk_nil2")
- (mk_fun (Tree.tagged_following_sibling_below tree) "Tree.tagged_sibling_ctx")
- (mk_fun (Tree.select_following_sibling_below tree) "Tree.select_sibling_ctx")
- (mk_fun (Tree.tagged_following_below tree) "Tree.tagged_foll_ctx")
- (mk_fun (Tree.select_following_below tree) "Tree.select_foll_ctx")
- (mk_fun (fun _ _ -> Tree.next_sibling_below tree) "[NEXTSIBLING]Tree.select_sibling_foll_ctx")
- (mk_fun (Tree.next_element_below tree) "Tree.next_element_ctx")
- (mk_fun (Tree.next_sibling_below tree) "Tree.node_sibling_ctx")
+ (Trace.mk_fun (fun _ _ -> Tree.nil) "Tree.mk_nil2")
+ (Trace.mk_fun (Tree.tagged_following_sibling_below tree) "Tree.tagged_sibling_ctx")
+ (Trace.mk_fun (Tree.select_following_sibling_below tree) "Tree.select_sibling_ctx")
+ (Trace.mk_fun (Tree.tagged_following_below tree) "Tree.tagged_foll_ctx")
+ (Trace.mk_fun (Tree.select_following_below tree) "Tree.select_foll_ctx")
+ (Trace.mk_fun (fun _ _ -> Tree.next_sibling_below tree) "[NEXTSIBLING]Tree.select_sibling_foll_ctx")
+ (Trace.mk_fun (Tree.next_element_below tree) "Tree.next_element_ctx")
+ (Trace.mk_fun (Tree.next_sibling_below tree) "Tree.node_sibling_ctx")
type t = fun_tree array array
let dummy = fun _ _ _ _ _ -> failwith "Uninitializd CodeCache"
- let default_line = Array.create 256 dummy (* 256 = max_tag *)
+ let default_line = Array.create 1024 dummy (* 1024 = max_tag *)
let create n = Array.create n default_line
let init f =
for i = 0 to (Array.length default_line) - 1
end
- let td_trans = CodeCache.create 10000 (* should be number of tags *number of states^2
- in the document *)
-
let empty_size n =
let rec loop acc = function 0 -> acc
| n -> loop (SList.cons StateSet.empty acc) (n-1)
type t = Obj.t array array array array
let dummy_val = Obj.repr ((),2,())
- let default_line3 = Array.create 10000 dummy_val
- let default_line2 = Array.create 10000 default_line3
- let default_line1 = Array.create 10000 default_line2
+ let default_line3 = Array.create BIG_A_SIZE dummy_val
+ let default_line2 = Array.create BIG_A_SIZE default_line3
+ let default_line1 = Array.create BIG_A_SIZE default_line2
let create n = Array.create n default_line1
if e == default then
let ne = Array.copy e in (set tab idx ne;ne)
else e
-
+
let add h tag fl s1 s2 (data: SList.t*bool*(merge_conf array)) =
let l1 = get_replace h tag default_line1 in
let l2 = get_replace l1 (Uid.to_int fl.Formlistlist.Node.id) default_line2 in
- let l3 = get_replace l2 (Uid.to_int s1.SList.Node.id) default_line3 in
+ let l3 = get_replace l2 (Uid.to_int s1.SList.Node.id) default_line3 in
set l3 (Uid.to_int s2.SList.Node.id) (Obj.repr data)
end
- let h_fold2 = Fold2Res.create 256
+
- let top_down ?(noright=false) a tree t slist ctx slot_size =
+ let top_down ?(noright=false) a tree t slist ctx slot_size td_trans h_fold2=
let pempty = empty_size slot_size in
let rempty = Array.make slot_size RS.empty in
(* evaluation starts from the right so we put sl1,res1 at the end *)
let _ = CodeCache.init mk_trans in
(if noright then loop_no_right else loop) t ctx slist Tag.dummy
- let run_top_down a tree =
- let init = SList.cons a.init SList.nil in
- let _,res = top_down a tree Tree.root init Tree.root 1
- in
- D_IGNORE_(
- output_trace a tree "trace.html"
- (RS.fold (fun t a -> IntSet.add (Tree.id tree t) a) res.(0) IntSet.empty),
+
+ let run_top_down a tree =
+ let init = SList.cons a.init SList.nil in
+ let _,res = top_down a tree Tree.root init Tree.root 1 (CodeCache.create BIG_A_SIZE) (Fold2Res.create 1024)
+ in
+ D_IGNORE_(
+ output_trace a tree "trace.html"
+ (RS.fold (fun t a -> IntSet.add (Tree.id tree t) a) res.(0) IntSet.empty),
res.(0))
- ;;
+ ;;
+
+
+
+
+
+ module Code3Cache =
+ struct
+ let get = Array.get
+ let set = Array.set
+ let realloc a new_size default =
+ let old_size = Array.length a in
+ if old_size == new_size then a
+ else if new_size == 0 then [||]
+ else let na = Array.create new_size default in
+ Array.blit a 0 na 0 old_size;na
+
+ type fun_tree = [`Tree] Tree.node -> [`Tree] Tree.node -> StateSet.t -> Tag.t -> StateSet.t*RS.t
+ and t = { mutable table : fun_tree array array;
+ mutable default_elm : fun_tree;
+ mutable default_line : fun_tree array;
+ (* statistics *)
+ mutable access : int;
+ mutable miss : int;
+ }
+
+
+ let create () =
+ { table = [||];
+ default_elm = (fun _ _ _ _ -> failwith "Uninitialized Code3Cache.t structure\n");
+ default_line = [||];
+ access = 0;
+ miss = 0 }
+
+ let init h f =
+ let default_line = Array.create SMALL_A_SIZE f in
+ begin
+ h.table <- Array.create SMALL_A_SIZE default_line;
+ h.default_elm <- f;
+ h.default_line <- default_line;
+ h.access <- 0;
+ h.miss <- 0
+ end
+
+ let next_power_of_2 n =
+ let rec loop i acc =
+ if acc == 0 then i
+ else loop (i+1) (acc lsr 1)
+ in
+ 1 lsl (loop 0 n)
+
+ let get_fun h slist tag =
+ let _ = h.access <- h.access + 1 in
+ let idx = Uid.to_int slist.StateSet.Node.id in
+ let line =
+ if idx >= Array.length h.table then
+ let new_tab = realloc h.table (next_power_of_2 idx) h.default_line in
+ let _ = h.miss <- h.miss + 1; h.table <- new_tab in h.default_line
+ else Array.unsafe_get h.table idx
+ in
+ if tag >= Array.length line then
+ let new_line = realloc line (next_power_of_2 tag) h.default_elm in
+ let _ = h.miss <- h.miss + 1; Array.unsafe_set h.table idx new_line in h.default_elm
+ else Array.unsafe_get line tag
+
+ let set_fun (h : t) slist tag (data : fun_tree) =
+ let idx = Uid.to_int slist.StateSet.Node.id in
+ let line =
+ if idx >= Array.length h.table then
+ let new_tab = realloc h.table (next_power_of_2 idx) h.default_line in
+ let _ = h.table <- new_tab in h.default_line
+ else Array.unsafe_get h.table idx
+ in
+ let line = if line == h.default_line then
+ let l = Array.copy line in Array.unsafe_set h.table idx l;l
+ else line in
+ let line = if tag >= Array.length line then
+ let new_line = realloc line (next_power_of_2 tag) h.default_elm in
+ let _ = Array.unsafe_set h.table idx new_line in new_line
+ else line
+ in
+ Array.unsafe_set line tag data
+
+
+ let dump h = Array.iteri
+ (fun id line -> if line != h.default_line then
+ begin
+ StateSet.print Format.err_formatter (StateSet.with_id (Uid.of_int id));
+ Format.fprintf Format.err_formatter " -> ";
+ Array.iteri (fun tag clos ->
+ if clos != h.default_elm then
+ Format.fprintf Format.err_formatter " (%s,%s) "
+ (Tag.to_string tag) (Trace.get_funname clos)) line;
+ Format.fprintf Format.err_formatter "\n%!"
+ end
+ ) h.table;
+ Format.fprintf Format.err_formatter "Cache hits: %i, Cache misses: %i, ratio = %f\n%!"
+ h.access h.miss ((float_of_int h.miss)/. (float_of_int h.access));
+ Format.fprintf Format.err_formatter "Size: %i kb\n%!"
+ (((2+(Array.length h.default_line)+
+ (Array.fold_left (fun acc l ->acc + (if l == h.default_line then 0 else Array.length l))
+ (Array.length h.table) h.table)) * Sys.word_size) / 1024)
+
+ end
+
+ module StaticEnv =
+ struct
+
+ type t = { stack : Obj.t array;
+ mutable top : int; }
+
+ let create () = { stack = Array.create BIG_A_SIZE (Obj.repr 0); top = 0 }
+ let add t e =
+ let _ = if t.top >= Array.length t.stack then failwith "Static Env overflow" in
+ let i = t.top in Array.unsafe_set t.stack i e; t.top <- i + 1; i
+
+ let get t i :'a = Obj.magic (Array.unsafe_get t.stack i)
+ end
+
+ module Fold3Res = struct
+ let get = Array.unsafe_get
+ let set = Array.set
+ external field1 : Obj.t -> int = "%field1"
+ type t = Obj.t array array array array
+ let dummy_val = Obj.repr ((),2,())
+
+ let default_line3 = Array.create 1024 dummy_val
+ let default_line2 = Array.create BIG_A_SIZE default_line3
+ let default_line1 = Array.create BIG_A_SIZE default_line2
+
+ let create n = Array.create n default_line1
+
+ let find h tag fl s1 s2 : StateSet.t*bool*merge_conf =
+ let l1 = get h (Uid.to_int fl.Formlist.Node.id) in
+ let l2 = get l1 (Uid.to_int s1.StateSet.Node.id) in
+ let l3 = get l2 (Uid.to_int s2.StateSet.Node.id) in
+ Obj.magic (get l3 tag)
+
+ let is_valid b = b != (Obj.magic dummy_val)
+ let get_replace tab idx default =
+ let e = get tab idx in
+ if e == default then
+ let ne = Array.copy e in (set tab idx ne;ne)
+ else e
+
+ let add h tag fl s1 s2 (data: StateSet.t*bool*merge_conf) =
+ let l1 = get_replace h (Uid.to_int fl.Formlist.Node.id) default_line1 in
+ let l2 = get_replace l1 (Uid.to_int s1.StateSet.Node.id) default_line2 in
+ let l3 = get_replace l2 (Uid.to_int s2.StateSet.Node.id) default_line3 in
+ set l3 tag (Obj.repr data)
+ end
+
+
+ let empty_res = StateSet.empty,RS.empty
+
+ let top_down1 a tree t slist ctx td_trans h_fold2 =
+ (* evaluation starts from the right so we put sl1,res1 at the end *)
+ let env = StaticEnv.create () in
+ let slist_reg = ref StateSet.empty in
+ let eval_fold2_slist fll t tag (sl2,res2) (sl1,res1) =
+ let data = Fold3Res.find h_fold2 tag fll sl1 sl2 in
+ if Fold3Res.is_valid data then
+ let r,b,conf = data in
+ (r,if b then RS.merge conf t res1 res2 else RS.empty)
+ else
+ let r,conf = eval_formlist tag sl1 sl2 fll in
+ let b = conf <> NO in
+ (Fold3Res.add h_fold2 tag fll sl1 sl2 (r,b,conf);
+ (r, if b then RS.merge conf t res1 res2 else RS.empty))
+
+ in
+ let loop t ctx slist _ =
+ if t == Tree.nil then empty_res else
+ let tag = Tree.tag tree t in
+ (Code3Cache.get_fun td_trans slist tag) t ctx slist tag
+
+ in
+ let loop_tag t ctx slist tag =
+ if t == Tree.nil then empty_res else
+ (Code3Cache.get_fun td_trans slist tag) t ctx slist tag
+
+ in
+ let mk_trans t ctx slist tag =
+ let fl_list,llist,rlist,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,_ = t.Transition.node 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;[]
+ )
+
+ ) slist (Formlist.nil,StateSet.empty,StateSet.empty,
+ StateSet.empty,StateSet.empty,StateSet.empty,StateSet.empty)
+
+ in
+ (* Logic to chose the first and next function *)
+ let tags_child,tags_below,tags_siblings,tags_after = Tree.tags tree tag in
+ let d_f = Algebra.decide a tags_child tags_below (StateSet.union ca da) true in
+ let d_n = Algebra.decide a tags_siblings tags_after (StateSet.union sa fa) false in
+ let f_kind,first = choose_jump_down tree d_f
+ and n_kind,next = choose_jump_next tree d_n in
+
+ let cont =
+ match f_kind,n_kind with
+ | `NIL,`NIL ->
+ fun t _ _ tag -> eval_fold2_slist fl_list t tag empty_res empty_res
+
+ | _,`NIL -> (
+ match f_kind with
+ |`TAG(tag1) ->
+ (fun t _ _ tag -> eval_fold2_slist fl_list t tag empty_res
+ (loop_tag (first t) t llist tag1))
+ | _ ->
+ fun t _ _ tag -> eval_fold2_slist fl_list t tag empty_res
+ (loop (first t) t llist tag)
+ )
+ | `NIL,_ -> (
+ match n_kind with
+ |`TAG(tag2) ->
+ fun t ctx _ tag ->
+ eval_fold2_slist fl_list t tag
+ (loop_tag (next t ctx) ctx rlist tag2)
+ empty_res
+
+ | _ ->
+ fun t ctx _ tag ->
+ eval_fold2_slist fl_list t tag
+ (loop (next t ctx) ctx rlist tag)
+ empty_res
+
+ )
+
+ | `TAG(tag1),`TAG(tag2) ->
+ fun t ctx _ tag ->
+ eval_fold2_slist fl_list t tag
+ (loop_tag (next t ctx) ctx rlist tag2)
+ (loop_tag (first t) t llist tag1)
+
+ | `TAG(tag1),`ANY ->
+ fun t ctx _ tag ->
+ eval_fold2_slist fl_list t tag
+ (loop (next t ctx) ctx rlist tag)
+ (loop_tag (first t) t llist tag1)
+
+ | `ANY,`TAG(tag2) ->
+ fun t ctx _ tag ->
+ eval_fold2_slist fl_list t tag
+ (loop_tag (next t ctx) ctx rlist tag2)
+ (loop (first t) t llist tag)
+
+
+ | _,_ ->
+ fun t ctx _ tag ->
+ eval_fold2_slist fl_list t tag
+ (loop (next t ctx) ctx rlist tag)
+ (loop (first t) t llist tag)
+
+
+
+ in
+ let _ = Trace.register_funname cont
+ (Printf.sprintf "{first=%s, next=%s}" (Trace.get_funname first) (Trace.get_funname next))
+ in
+ Code3Cache.set_fun td_trans slist tag cont;
+ cont
+ in
+ let cache_take_trans t ctx slist tag =
+ let cont = mk_trans t ctx slist tag in
+ cont t ctx slist tag
+ in
+ Code3Cache.init td_trans (cache_take_trans);
+ loop t ctx slist Tag.dummy
+
+
+ let run_top_down1 a tree =
+ let code_cache = Code3Cache.create () in
+ let fold_cache = Fold3Res.create BIG_A_SIZE in
+ let _,res = top_down1 a tree Tree.root a.init Tree.root code_cache fold_cache
+ in
+ (*Code3Cache.dump code_cache; *)
+ res
+
module Configuration =
struct
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,Uid.to_int (Ptset.Int.uid s));
+ { hash = HASHINT2(c.hash,Uid.to_int s.StateSet.Node.id);
sets = Ptss.add s c.sets;
results = IMap.add s r c.results
}
in
let h,s =
Ptss.fold
- (fun s (ah,ass) -> (HASHINT2(ah, Uid.to_int (Ptset.Int.uid s)),
+ (fun s (ah,ass) -> (HASHINT2(ah, Uid.to_int s.StateSet.Node.id ),
Ptss.add s ass))
(Ptss.union c1.sets c2.sets) (0,Ptss.empty)
in
Hashtbl.find h_fold key
with
Not_found -> let res =
- if dir then eval_formlist tag s Ptset.Int.empty formlist
- else eval_formlist tag Ptset.Int.empty s formlist
+ if dir then eval_formlist tag s StateSet.empty formlist
+ else eval_formlist tag StateSet.empty s formlist
in (Hashtbl.add h_fold key res;res)
in
let (rb,rb1,rb2,mark) = bool_of_merge mcnf in
let slist = SList.rev (slist) in
let newconf = fold_f_conf tree 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
+ if StateSet.intersect s init then
( RS.concat res ar ,nc)
else (ar,Configuration.add nc s res))
(newconf.Configuration.results) (accu,Configuration.empty)
| 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
+ then StateSet.add q acc
+ else acc) a.trans StateSet.empty
in Hashtbl.add h_tdconf tag res;res
in
(* let _ = pr ", among ";
pr "\n%!";
in *)
let r = SList.cons r SList.nil in
- let set,res = top_down (~noright:noright) a tree t r t 1 in
+ let set,res = top_down (~noright:noright) a tree t r t 1 (CodeCache.create BIG_A_SIZE) (Fold2Res.create 1024) in
let set = match SList.node set with
| SList.Cons(x,_) ->x
| _ -> assert false
end
- let top_down_count a t = let module RI = Run(Integer) in let r = Integer.length (RI.run_top_down a t)
- in (*RI.TransCache.dump RI.td_trans; *)r
- let top_down a t = let module RI = Run(IdSet) in (RI.run_top_down a t)
+ let top_down_count a t = let module RI = Run(Integer) in Integer.length (RI.run_top_down a t)
+ let top_down_count1 a t = let module RI = Run(Integer) in Integer.length (RI.run_top_down1 a t)
+ let top_down a t = let module RI = Run(IdSet) in (RI.run_top_down a t)
+ let top_down1 a t = let module RI = Run(IdSet) in (RI.run_top_down1 a t)
let bottom_up_count a t k = let module RI = Run(Integer) in Integer.length (RI.run_bottom_up a t k)
let bottom_up a t k = let module RI = Run(IdSet) in (RI.run_bottom_up a t k)
struct
module Results = GResult(Doc)
let top_down a t = let module R = Run(Results) in (R.run_top_down a t)
+ let top_down1 a t = let module R = Run(Results) in (R.run_top_down1 a t)
end