INCLUDE "utils.ml"
INCLUDE "debug.ml"
-open Format
-open Misc
-open Bigarray
-type stats = { run : int;
- tree_size : int;
- fetch_trans_cache_access : int;
- fetch_trans_cache_hit : int;
- eval_trans_cache_access : int;
- eval_trans_cache_hit : int;
- }
-
-let fetch_trans_cache_hit = ref 0
-let fetch_trans_cache_access = ref 0
-let eval_trans_cache_hit = ref 0
-let eval_trans_cache_access = ref 0
-let reset_stat_counters () =
- fetch_trans_cache_hit := 0;
- fetch_trans_cache_access := 0;
- eval_trans_cache_hit := 0;
- eval_trans_cache_access := 0
-
-
-module NodeSummary =
+module Make (T : Tree.S) =
struct
- (* Pack into an integer the result of the is_* and has_ predicates
- for a given node *)
- type t = int
- let dummy = -1
- (*
- ...44443210
- ...4444 -> kind
- 3 -> has_right
- 2 -> has_left
- 1 -> is_right
- 0 -> is_left
- *)
- let is_left (s : t) : bool =
- s land 1 != 0
-
- let is_right (s : t) : bool =
- s land 0b10 != 0
-
- let has_left (s : t) : bool =
- s land 0b100 != 0
-
- let has_right (s : t) : bool =
- s land 0b1000 != 0
-
- let kind (s : t) : Tree.NodeKind.t =
- Obj.magic (s lsr 4)
-
- let make is_left is_right has_left has_right kind =
- (int_of_bool is_left) lor
- ((int_of_bool is_right) lsl 1) lor
- ((int_of_bool has_left) lsl 2) lor
- ((int_of_bool has_right) lsl 3) lor
- ((Obj.magic kind) lsl 4)
- end
-
- let dummy_set = StateSet.singleton State.dummy
-
-
-
-IFDEF HTMLTRACE
-THEN
- type sat_array = StateSet.t array list
- DEFINE IFHTML(a,b) = (a)
-ELSE
- type sat_array = StateSet.t array
- DEFINE IFHTML(a,b) = (b)
-END
-
- let unsafe_get a i =
- if i < 0 then StateSet.empty else
- Array.unsafe_get (IFHTML(List.hd a, a)) i
-
- let unsafe_set a i v old_v =
- if v != old_v then
- Array.unsafe_set (IFHTML(List.hd a, a)) i v
-
- type 'a run = {
- tree : 'a ;
- (* The argument of the run *)
- auto : Ata.t;
- (* The automaton to be run *)
- mutable sat: sat_array;
- (* A mapping from node preorders to states satisfied at that node *)
- mutable pass : int;
- (* Number of run we have performed *)
- mutable fetch_trans_cache : Ata.Formula.t Cache.N2.t;
- (* A cache from states * label to list of transitions *)
- mutable td_cache : StateSet.t Cache.N6.t;
- mutable bu_cache : StateSet.t Cache.N6.t;
- (* Two 6-way caches used during the top-down and bottom-up phase
- label * self-set * fc-set * ns-set * parent-set * node-shape -> self-set
- *)
- node_summaries: (int, int16_unsigned_elt, c_layout) Array1.t;
-
- }
-
- let dummy_form = Ata.Formula.stay State.dummy
-
- let get_form fetch_trans_cache auto tag q =
- let phi =
- incr fetch_trans_cache_access;
- Cache.N2.find fetch_trans_cache (tag.QName.id :> int) (q :> int)
- in
- if phi == dummy_form then
- let phi = Ata.get_form auto tag q in
- let () =
- Cache.N2.add
- fetch_trans_cache
- (tag.QName.id :> int)
- (q :> int) phi
- in phi
- else begin
- incr fetch_trans_cache_hit;
- phi
- end
-
-
- let eval_form phi fcs nss ps ss summary =
- let open Ata in
- let rec loop phi =
- begin match Formula.expr phi with
- | Boolean.False -> false
- | Boolean.True -> true
- | Boolean.Atom (a, b) ->
- begin
- let open NodeSummary in
- match a.Atom.node with
- | Move (m, q) ->
- b && StateSet.mem q (
- match m with
- `First_child -> fcs
- | `Next_sibling -> nss
- | `Parent | `Previous_sibling -> ps
- | `Stay -> ss
- )
- | Is_first_child -> b == is_left summary
- | Is_next_sibling -> b == is_right summary
- | Is k -> b == (k == kind summary)
- | Has_first_child -> b == has_left summary
- | Has_next_sibling -> b == has_right summary
- end
- | Boolean.And(phi1, phi2) -> loop phi1 && loop phi2
- | Boolean.Or (phi1, phi2) -> loop phi1 || loop phi2
- end
- in
- loop phi
-
-
- let eval_trans_aux auto trans_cache tag summary fcs nss ps sat todo =
- StateSet.fold (fun q (a_sat) ->
- let phi =
- get_form trans_cache auto tag q
- in
- if eval_form phi fcs nss ps a_sat summary then
- StateSet.add q a_sat
- else a_sat
- ) todo sat
-
- let rec eval_trans_fix auto trans_cache tag summary fcs nss ps sat todo =
- let new_sat =
- eval_trans_aux auto trans_cache tag summary fcs nss ps sat todo
- in
- if new_sat == sat then sat else
- eval_trans_fix auto trans_cache tag summary fcs nss ps new_sat todo
-
-
- let eval_trans auto fetch_trans_cache eval_cache tag summary fcs nss ps ss todo =
- let fcsid = (fcs.StateSet.id :> int) in
- let nssid = (nss.StateSet.id :> int) in
- let psid = (ps.StateSet.id :> int) in
- let ssid = (ss.StateSet.id :> int) in
- let tagid = (tag.QName.id :> int) in
- let res = Cache.N6.find eval_cache tagid summary ssid fcsid nssid psid in
- incr eval_trans_cache_access;
- if res != dummy_set then begin incr eval_trans_cache_hit; res end
- else let new_sat =
- eval_trans_fix auto fetch_trans_cache tag summary fcs nss ps ss todo
+ let int (x : bool) : int = Obj.magic x
+ let kint (x : Tree.NodeKind.t) : int = Obj.magic x
+ let summary tree node parent fc ns =
+ (int (ns != T.nil)) lor
+ ((int (fc != T.nil)) lsl 1) lor
+ ((int (node == T.next_sibling tree parent)) lsl 2) lor
+ ((int (node == T.first_child tree parent)) lsl 3) lor
+ ((kint (T.kind tree node)) lsl 4)
+
+ let has_next_sibling summary : bool = Obj.magic (summary land 1)
+ let has_first_child summary : bool = Obj.magic ((summary lsr 1) land 1)
+ let is_next_sibling summary : bool = Obj.magic ((summary lsr 2) land 1)
+ let is_first_child summary : bool = Obj.magic ((summary lsr 3) land 1)
+ let kind summary : Tree.NodeKind.t = Obj.magic (summary lsr 4)
+
+
+ let eval_form phi node_summary f_set n_set p_set s_set =
+ let rec loop phi =
+ let open Boolean in
+ match Ata.Formula.expr phi with
+ False -> false
+ | True -> true
+ | Or (phi1, phi2) -> loop phi1 || loop phi2
+ | And (phi1, phi2) -> loop phi1 && loop phi2
+ | Atom (a, b) -> b == Ata.(
+ match Atom.node a with
+ Is_first_child -> is_first_child node_summary
+ | Is_next_sibling -> is_next_sibling node_summary
+ | Is k -> k == kind node_summary
+ | Has_first_child -> has_first_child node_summary
+ | Has_next_sibling -> has_next_sibling node_summary
+ | Move (m, q) ->
+ let set =
+ match m with
+ `First_child -> f_set
+ | `Next_sibling -> n_set
+ | `Parent
+ | `Previous_sibling -> p_set
+ | `Stay -> s_set
in
- Cache.N6.add eval_cache tagid summary ssid fcsid nssid psid new_sat;
- new_sat
-
+ StateSet.mem q set
+ )
+ in
+ loop phi
-module Make (T : Tree.S) (L : Node_list.S with type node = T.node) =
- struct
- let make auto tree =
- let len = T.size tree in
- {
- tree = tree;
- auto = auto;
- sat = (let a = Array.create len StateSet.empty in
- IFHTML([a], a));
- pass = 0;
- fetch_trans_cache = Cache.N2.create dummy_form;
- td_cache = Cache.N6.create dummy_set;
- bu_cache = Cache.N6.create dummy_set;
- node_summaries = let ba = Array1.create int16_unsigned c_layout len in
- Array1.fill ba 0; ba
- }
+ let eval_trans_aux trans_list node_summary f_set n_set p_set s_set =
+ let open Ata in
+ TransList.fold (fun trs acc ->
+ let q, _ , phi = Transition.node trs in
+ if eval_form phi node_summary f_set n_set p_set s_set then
+ StateSet.add q acc
+ else
+ acc) trans_list s_set
+ let eval_trans trans_list node_summary f_set n_set p_set s_set =
+ let rec loop old_s =
- let top_down run update_res =
- let i = run.pass in
- let tree = run.tree in
- let auto = run.auto in
- let states_by_rank = Ata.get_states_by_rank auto in
- let td_todo = states_by_rank.(i) in
- let bu_todo =
- if i == Array.length states_by_rank - 1 then StateSet.empty
- else
- states_by_rank.(i+1)
+ let new_s =
+ eval_trans_aux trans_list node_summary f_set n_set p_set old_s
+ in
+ if new_s == old_s then old_s else loop new_s
in
- let last_run = i >= Array.length states_by_rank - 2 in
- let rec loop_td_and_bu node parent parent_sat =
- if node == T.nil then StateSet.empty
- else begin
- let node_id = T.preorder tree node in
- let fc = T.first_child tree node in
- let ns = T.next_sibling tree node in
- (* We enter the node from its parent *)
- let summary =
- let s = Array1.unsafe_get run.node_summaries node_id in
- if s != 0 then s else
- let s =
- NodeSummary.make
- (node_id == T.preorder tree (T.first_child tree parent)) (*is_left *)
- (node_id == T.preorder tree (T.next_sibling tree parent))(*is_right *)
- (fc != T.nil) (* has_left *)
- (ns != T.nil) (* has_right *)
- (T.kind tree node) (* kind *)
- in
- run.node_summaries.{node_id} <- s; s
+ loop s_set
+
+ let dummy_set = StateSet.singleton State.dummy
+ let count = ref 0
+ let total = ref 0
+ let () = at_exit (fun () -> Format.eprintf "Cache miss: %i/%i\n%!" !count !total)
+
+ let eval_trans auto cache set tag node_summary f_set n_set p_set s_set =
+ incr total;
+ let i = (tag.QName.id :> int) in
+ let j = node_summary in
+ let k = (f_set.StateSet.id :> int) in
+ let l = (n_set.StateSet.id :> int) in
+ let m = (p_set.StateSet.id :> int) in
+ let n = (s_set.StateSet.id :> int) in
+ let res = Cache.N6.find cache i j k l m n in
+ if res == dummy_set then begin
+ incr count;
+ let trans_list = Ata.get_trans auto tag set in
+ let res = eval_trans trans_list node_summary f_set n_set p_set s_set in
+ Cache.N6.add cache i j k l m n res;
+ res
+ end
+ else res
+
+
+ let auto_run auto tree prev_nodes td_states bu_states exit_states _i =
+ if false then
+ Format.eprintf "Doing a td (with states: %a) and a bu (with states: %a), exit states are: %a @\n@."
+ StateSet.print td_states
+ StateSet.print bu_states
+ StateSet.print exit_states;
+ let td_cache = Cache.N6.create dummy_set in
+ let bu_cache = Cache.N6.create dummy_set in
+ let rec loop res node parent parent_set =
+ if node == T.nil then StateSet.empty else begin
+ let set,lset,rset =
+ if Sequence.is_empty prev_nodes then
+ StateSet.(empty,empty,empty)
+ else
+ let set,lset,rset, node' = Sequence.peek prev_nodes in
+ if node == node' then begin
+ ignore (Sequence.pop prev_nodes);
+ set,lset,rset
+ end
+ else
+ StateSet.(empty,empty,empty)
in
- let status0 = unsafe_get run.sat node_id in
- (* get the node_statuses for the first child, next sibling and parent *)
- (* evaluate the transitions with all this statuses *)
let tag = T.tag tree node in
+ let first_child = T.first_child tree node in
+ let next_sibling = T.next_sibling tree node in
+ let node_summary = summary tree node parent first_child next_sibling in
+
let status1 =
- eval_trans
- auto run.fetch_trans_cache run.td_cache tag
- summary
- (unsafe_get run.sat (T.preorder tree fc))
- (unsafe_get run.sat (T.preorder tree ns))
- parent_sat
- status0 td_todo
+ eval_trans auto td_cache td_states tag node_summary lset rset parent_set set
in
+ let fcs = loop res first_child node status1 in
+ let rres = Sequence.create () in
+ let nss = loop rres next_sibling node status1 in
- (* update the cache if the status of the node changed
- unsafe_set run.sat node_id status1 status0;*)
- if bu_todo == StateSet.empty then begin
- unsafe_set run.sat node_id status1 status0; (* write the td_states *)
- update_res false status1 node;
- let _ = loop_td_and_bu fc node status1 in
- loop_td_and_bu ns node status1 (* tail call *)
- end else
- let fcs1, nss1 =
- if last_run then
- let nss1 = loop_td_and_bu ns node status1 in
- let fcs1 = loop_td_and_bu fc node status1 in
- fcs1, nss1
- else
- let fcs1 = loop_td_and_bu fc node status1 in
- let nss1 = loop_td_and_bu ns node status1 in
- fcs1, nss1
- in
- let status2 =
- eval_trans auto run.fetch_trans_cache run.bu_cache tag
- summary fcs1
- nss1
- parent_sat
- status1 bu_todo
- in
- unsafe_set run.sat node_id status2 status0;
- if last_run then update_res true status2 node;
- status2
- end
+ let status2 =
+ eval_trans auto bu_cache bu_states tag node_summary fcs nss parent_set status1
+ in
+ let mstates = StateSet.inter status2 exit_states in
+ if false then begin
+ Format.eprintf "On node %i (tag : %a) status0 = %a, status1 = %a, fcs = %a, nss = %a, par = %a, status2 = %a, mstates = %a@\n@."
+ (T.preorder tree node)
+ QName.print tag
+ StateSet.print set
+ StateSet.print status1
+ StateSet.print fcs
+ StateSet.print nss
+ StateSet.print parent_set
+ StateSet.print status2
+ StateSet.print mstates;
+ end;
+ if mstates != StateSet.empty then
+ Sequence.push_front (mstates,
+ StateSet.inter exit_states fcs,
+ StateSet.inter exit_states nss, node) res;
+ Sequence.append res rres;
+ status2
+ end
in
- let _ = loop_td_and_bu (T.root tree) T.nil dummy_set in
- run.pass <- run.pass + 2
-
-
- let mk_update_result auto =
- let sel_states = Ata.get_selecting_states auto in
- let res = L.create () in
- (fun prepend sat node ->
- if StateSet.intersect sel_states sat then begin
- if prepend then L.push_front node res else
- L.push_back node res
- end),
- (fun () -> res)
+ let res = Sequence.create () in
+ ignore (loop res (T.root tree) T.nil StateSet.empty);
+ if false then Format.eprintf "Finished pass: %i @\n-----------------------@\n@." _i;
+ res
+
+
+
+ let prepare_run auto l =
+ let res = Sequence.create () in
+ let start = Ata.get_starting_states auto in
+ Sequence.iter (fun n -> Sequence.push_back (start, StateSet.empty, StateSet.empty, n) res) l;
+ res
+
+
+ let main_eval auto tree nodes =
+ let s_nodes = prepare_run auto nodes in
+
+ let ranked_states = Ata.get_states_by_rank auto in
+ let acc = ref s_nodes in
+ let max_rank = Ata.get_max_rank auto in
+ for i = 0 to max_rank do
+ let open Ata in
+ let { td; bu; exit } = ranked_states.(i) in
+ acc := auto_run auto tree !acc td bu exit i;
+ if false then begin
+ Format.eprintf "Intermediate result is: @\n";
+ Sequence.iter (fun (s,_,_, n) ->
+ Format.eprintf "{%a, %i (%a)} "
+ StateSet.print s
+ (T.preorder tree n)
+ QName.print (T.tag tree n)) !acc;
+ Format.eprintf "@\n@.";
+ end
-
- let mk_update_full_result auto =
- let dummy = L.create () in
- let res_mapper = Cache.N1.create dummy in
- let () =
- StateSet.iter
- (fun q -> Cache.N1.add res_mapper (q :> int) (L.create()))
- (Ata.get_selecting_states auto)
- in
- (fun prepend sat node ->
- StateSet.iter
- (fun q ->
- let res = Cache.N1.find res_mapper (q :> int) in
- if res != dummy then begin
- if prepend then L.push_front node res
- else L.push_back node res
- end
- ) sat),
- (fun () ->
- StateSet.fold_right
- (fun q acc -> (q, Cache.N1.find res_mapper (q :> int))::acc)
- (Ata.get_selecting_states auto) [])
-
- let prepare_run run list =
- let tree = run.tree in
- let auto = run.auto in
- let sat = IFHTML((List.hd run.sat), run.sat) in
- let sat0 = Ata.get_starting_states auto in
- L.iter (fun node ->
- let node_id = T.preorder tree node in
- sat.(node_id) <- sat0) list
-
- let tree_size = ref 0
- let pass = ref 0
-
- let compute_run auto tree nodes update_res =
- pass := 0;
- tree_size := T.size tree;
- let run = make auto tree in
- prepare_run run nodes;
- let rank = Ata.get_max_rank auto in
- while run.pass <= rank do
- top_down run update_res;
- IFHTML((run.sat <- (Array.copy (List.hd run.sat)) :: run.sat), ());
- run.td_cache <- Cache.N6.create dummy_set;
- run.bu_cache <- Cache.N6.create dummy_set;
done;
- IFHTML((run.sat <- List.tl run.sat), ());
- pass := Ata.get_max_rank auto + 1;
- IFHTML(Html_trace.gen_trace auto run.sat (module T : Tree.S with type t = T.t) tree ,());
- run
-
-
-
- let full_eval auto tree nodes =
- let update_full,get_full = mk_update_full_result auto in
- let _ = compute_run auto tree nodes update_full in
- get_full ()
+ !acc
let eval auto tree nodes =
- let update_res,get_res = mk_update_result auto in
- let _ = compute_run auto tree nodes update_res in
- get_res ()
+ let res = main_eval auto tree nodes in
+ let r = Sequence.create () in
+ Sequence.iter (fun (_,_,_, n) -> Sequence.push_back n r) res;
+ r
- let stats () = {
- tree_size = !tree_size;
- run = !pass;
- fetch_trans_cache_access = !fetch_trans_cache_access;
- fetch_trans_cache_hit = !fetch_trans_cache_hit;
- eval_trans_cache_access = !eval_trans_cache_access;
- eval_trans_cache_hit = !eval_trans_cache_hit;
- }
+ let full_eval auto tree nodes =
+ let res = main_eval auto tree nodes in
+ let dummy = Sequence.create () in
+ let cache = Cache.N1.create dummy in
+ Sequence.iter (fun (set, _, _, n) ->
+ StateSet.iter (fun q ->
+ let qres = Cache.N1.find cache q in
+ let qres =
+ if qres == dummy then begin
+ let s = Sequence.create () in
+ Cache.N1.add cache q s;
+ s
+ end
+ else qres
+ in
+ Sequence.push_back n qres) set )
+ res;
+ let l = StateSet.fold (fun q acc ->
+ let res = Cache.N1.find cache q in
+ (q, res) :: acc) (Ata.get_selecting_states auto) []
+ in
+ List.rev l
end