(***********************************************************************)
(*
- Time-stamp: <Last modified on 2013-03-13 14:56:29 CET by Kim Nguyen>
+ Time-stamp: <Last modified on 2013-03-13 19:02:13 CET by Kim Nguyen>
*)
INCLUDE "utils.ml"
open Format
open Utils
-module Make (T : Tree.Sig.S) = struct
+module Make (T : Tree.Sig.S) :
+ sig
+ val eval : Ata.t -> T.t -> T.node -> T.node list
+ end
+ = struct
- type cache = (int, StateSet.t) Hashtbl.t
+ type cache = StateSet.t Cache.N1.t
+ let get c t n = Cache.N1.find c (T.preorder t n)
- let get c t n =
- try Hashtbl.find c (T.preorder t n)
- with Not_found -> StateSet.empty
+ let set c t n v = Cache.N1.add c (T.preorder t n) v
- let set c t n v = Hashtbl.replace c (T.preorder t n) v
- let eval_form phi tree node fcs nss ps ss =
+ module Info = struct
+ type t = { is_left : bool;
+ is_right : bool;
+ has_left : bool;
+ has_right : bool;
+ kind : Tree.Common.NodeKind.t;
+ }
+ let equal a b = a = b
+ let hash a = Hashtbl.hash a
+ end
+
+ module NodeInfo = Hcons.Make(Info)
+
+ let eval_form phi node_info fcs nss ps ss =
+ let open NodeInfo in
+ let open Info in
let rec loop phi =
- match Ata.SFormula.expr phi with
+ begin match Ata.SFormula.expr phi with
Formula.True -> true
| Formula.False -> false
| Formula.Atom a ->
let p, b, q = Ata.Atom.node a in
let pos =
let open Ata in
- match p with
- | First_child -> StateSet.mem q fcs
- | Next_sibling -> StateSet.mem q nss
- | Parent | Previous_sibling -> StateSet.mem q ps
- | Stay -> StateSet.mem q ss
- | Is_first_child ->
- node == (T.first_child tree (T.parent tree node))
- | Is_next_sibling ->
- node == (T.next_sibling tree (T.parent tree node))
- | Is k -> k == (T.kind tree node)
- | Has_first_child ->
- T.nil != T.first_child tree node
- | Has_next_sibling ->
- T.nil != T.next_sibling tree node
- in
- if Ata.is_move p && (not b) then
- eprintf "Warning: Invalid negative atom %a" Ata.Atom.print a;
- b == pos
+ match p with
+ | First_child -> StateSet.mem q fcs
+ | Next_sibling -> StateSet.mem q nss
+ | Parent | Previous_sibling -> StateSet.mem q ps
+ | Stay -> StateSet.mem q ss
+ | Is_first_child -> node_info.node.is_left
+ | Is_next_sibling -> node_info.node.is_right
+ | Is k -> k == node_info.node.kind
+ | Has_first_child -> node_info.node.has_left
+ | Has_next_sibling -> node_info.node.has_right
+ in
+ if Ata.is_move p && (not b) then
+ eprintf "Warning: Invalid negative atom %a" Ata.Atom.print a;
+ b == pos
| Formula.And(phi1, phi2) -> loop phi1 && loop phi2
| Formula.Or (phi1, phi2) -> loop phi1 || loop phi2
+ end
in
loop phi
- let eval_trans l tree node fcs nss ps ss acc =
- List.fold_left (fun (acct, accs) ((q, phi) as trs) ->
- if StateSet.mem q accs then (acct, accs) else
- if eval_form phi tree node fcs nss ps ss then
- (acct, StateSet.add q accs)
+ let eval_trans cache ltrs node_info fcs nss ps ss =
+ let j = (node_info.NodeInfo.id :> int)
+ and k = (fcs.StateSet.id :> int)
+ and l = (nss.StateSet.id :> int)
+ and m = (ps.StateSet.id :> int) in
+ let rec loop ltrs ss =
+ let i = (ltrs.Ata.TransList.id :> int)
+ and n = (ss.StateSet.id :> int) in
+ let (new_ltrs, new_ss) as res =
+ let res = Cache.N6.find cache i j k l m n in
+ if res == Cache.N6.dummy cache then
+ let res =
+ Ata.TransList.fold (fun trs (acct, accs) ->
+ let q, _, phi = Ata.Transition.node trs in
+ if StateSet.mem q accs then (acct, accs) else
+ if eval_form phi node_info fcs nss ps accs then
+ (acct, StateSet.add q accs)
+ else
+ (Ata.TransList.cons trs acct, accs)
+ ) ltrs (Ata.TransList.nil, ss)
+ in
+ Cache.N6.add cache i j k l m n res; res
else
- (trs::acct, accs)
- ) ([], acc) l
+ res
+ in
+ if new_ss == ss then res else
+ loop new_ltrs new_ss
+ in
+ loop ltrs ss
let top_down_run auto tree node cache _i =
let redo = ref false in
+ let dummy2 = Ata.TransList.cons
+ (Ata.Transition.make (State.dummy,QNameSet.empty, Ata.SFormula.false_))
+ Ata.TransList.nil
+ in
+ let dummy6 = (dummy2, StateSet.empty) in
+ let trans_cache6 = Cache.N6.create 17 dummy6 in
+ let trans_cache2 = Cache.N2.create 17 dummy2 in
let rec loop node =
if node != T.nil then begin
let parent = T.parent tree node in
let fc = T.first_child tree node in
let ns = T.next_sibling tree node in
- let states0 = get cache tree node in
let tag = T.tag tree node in
- let trans0 = Ata.get_trans auto auto.Ata.states tag in
+ let states0 = get cache tree node in
+ let trans0 =
+ let trs =
+ Cache.N2.find trans_cache2
+ (tag.QName.id :> int) (auto.Ata.states.StateSet.id :> int)
+ in
+ if trs == dummy2 then
+ let trs = Ata.get_trans auto auto.Ata.states tag in
+ (Cache.N2.add
+ trans_cache2
+ (tag.QName.id :> int)
+ (auto.Ata.states.StateSet.id :> int) trs; trs)
+ else trs
+ in
let ps = get cache tree parent in
let fcs = get cache tree fc in
let nss = get cache tree ns in
+ let node_info = NodeInfo.make
+ (Info.({ is_left = node == T.first_child tree parent;
+ is_right = node == T.next_sibling tree parent;
+ has_left = fc != T.nil;
+ has_right = ns != T.nil;
+ kind = T.kind tree node }))
+ in
let trans1, states1 =
- eval_trans trans0 tree node fcs nss ps states0 states0
+ eval_trans trans_cache6 trans0 node_info fcs nss ps states0
in
if states1 != states0 then set cache tree node states1;
let () = loop fc in
let fcs1 = get cache tree fc in
let trans2, states2 =
- eval_trans trans1 tree node fcs1 nss ps states1 states1
+ eval_trans trans_cache6 trans1 node_info fcs1 nss ps states1
in
if states2 != states1 then set cache tree node states2;
let () = loop ns in
let _, states3 =
- eval_trans trans2 tree node fcs1 (get cache tree ns) ps states2 states2
+ eval_trans trans_cache6 trans2 node_info fcs1 (get cache tree ns) ps states2
in
if states3 != states2 then set cache tree node states3;
if states0 != states3 && (not !redo) then redo := true
loop node []
let eval auto tree node =
- let cache = Hashtbl.create 511 in
+ let cache = Cache.N1.create (T.size tree) StateSet.empty in
let redo = ref true in
let iter = ref 0 in
while !redo do