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8026ca9)
- Need to fix attributes handling
- Need to add preceding/following
(***********************************************************************)
(*
(***********************************************************************)
(*
- Time-stamp: <Last modified on 2013-03-05 16:31:57 CET by Kim Nguyen>
+ Time-stamp: <Last modified on 2013-03-05 18:25:03 CET by Kim Nguyen>
*)
INCLUDE "utils.ml"
open Format
open Utils
*)
INCLUDE "utils.ml"
open Format
open Utils
-type move = [ `Left | `Right | `Up1 | `Up2 | `Epsilon ]
+type move = [ `Left | `Right | `Up1 | `Up2 | `Epsilon |`Is1 |`Is2 ]
type state_ctx = { mutable left : StateSet.t;
mutable right : StateSet.t;
mutable up1 : StateSet.t;
mutable up2 : StateSet.t;
type state_ctx = { mutable left : StateSet.t;
mutable right : StateSet.t;
mutable up1 : StateSet.t;
mutable up2 : StateSet.t;
- mutable epsilon : StateSet.t}
+ mutable epsilon : StateSet.t;
+ mutable is_left : bool;
+ mutable is_root : bool}
type pred_ = move * bool * State.t
type pred_ = move * bool * State.t
-let make_ctx a b c d e =
- { left = a; right = b; up1 = c; up2 = d; epsilon = e }
+let make_ctx a b c d e f g =
+ { left = a; right = b; up1 = c; up2 = d; epsilon = e; is_left = f; is_root = g }
-let print_ctx fmt c = fprintf fmt "{ left : %a; right : %a; up1: %a ; up2 : %a; epsilon : %a }"
+let print_ctx fmt c = fprintf fmt "{ left : %a; right : %a; up1: %a ; up2 : %a; epsilon : %a ; is_left : %b; is_root : %b }"
StateSet.print c.left StateSet.print c.right StateSet.print c.up1 StateSet.print c.up2
StateSet.print c.epsilon
StateSet.print c.left StateSet.print c.right StateSet.print c.up1 StateSet.print c.up2
StateSet.print c.epsilon
module Move : (Formula.PREDICATE with type data = pred_ and type ctx = state_ctx ) =
struct
module Move : (Formula.PREDICATE with type data = pred_ and type ctx = state_ctx ) =
struct
| `Epsilon -> Pretty.epsilon, ""
| `Up1 -> Pretty.up_arrow, Pretty.subscript 1
| `Up2 -> Pretty.up_arrow, Pretty.subscript 2
| `Epsilon -> Pretty.epsilon, ""
| `Up1 -> Pretty.up_arrow, Pretty.subscript 1
| `Up2 -> Pretty.up_arrow, Pretty.subscript 2
+ | `Is1 -> "?", Pretty.subscript 1
+ | `Is2 -> "?", Pretty.subscript 2
in
fprintf _str_fmt "%s%s" dir num;
in
fprintf _str_fmt "%s%s" dir num;
- State.print _str_fmt s;
+ if s != State.dummy then State.print _str_fmt s;
let str = _flush_str_fmt () in
let str = _flush_str_fmt () in
- if b then fprintf ppf "%s" str
- else Pretty.pp_overline ppf str
-
+ fprintf ppf "%s%s" (if b then "" else Pretty.lnot) str
let neg p =
let l, b, s = p.node in
make (l, not b, s)
let neg p =
let l, b, s = p.node in
make (l, not b, s)
exception NegativeAtom of (move*State.t)
exception NegativeAtom of (move*State.t)
let eval ctx p =
let l, b, s = p.node in
let eval ctx p =
let l, b, s = p.node in
- if not b then raise (NegativeAtom(l,s));
- StateSet.mem s begin
- match l with
- `Left -> ctx.left
- | `Right -> ctx.right
- | `Up1 -> ctx.up1
- | `Up2 -> ctx.up2
- | `Epsilon -> ctx.epsilon
+ if s == State.dummy then
+ let dir =
+ match l with
+ | `Is1 -> ctx.is_left
+ | _ -> not ctx.is_left
+ in
+ let res = dir && not ctx.is_root in
+ res && b || (not (b || res))
+ else begin
+ if not b then raise (NegativeAtom(l,s));
+ StateSet.mem s begin
+ match l with
+ `Left -> ctx.left
+ | `Right -> ctx.right
+ | `Up1 -> ctx.up1
+ | `Up2 -> ctx.up2
+ | `Epsilon -> ctx.epsilon
+ | _ -> StateSet.empty
+ end
| Formula.And(f1, f2) -> (if b then SFormula.and_ else SFormula.or_)(flip b f1) (flip b f2)
| Formula.Atom(a) -> begin
let l, b', q = Move.node a in
| Formula.And(f1, f2) -> (if b then SFormula.and_ else SFormula.or_)(flip b f1) (flip b f2)
| Formula.Atom(a) -> begin
let l, b', q = Move.node a in
+ if q == State.dummy then if b then f else SFormula.not_ f
+ else
+ if b == b' then begin
(* a appears positively, either no negation or double negation *)
(* a appears positively, either no negation or double negation *)
- if not (Hashtbl.mem memo_state (q,b)) then Queue.add (q,true) todo;
- SFormula.atom_ (Move.make (l, true, q))
- end else begin
+ if not (Hashtbl.mem memo_state (q,b)) then Queue.add (q,true) todo;
+ SFormula.atom_ (Move.make (l, true, q))
+ end else begin
(* need to reverse the atom
either we have a positive state deep below a negation
or we have a negative state in a positive formula
(* need to reverse the atom
either we have a positive state deep below a negation
or we have a negative state in a positive formula
Not_found ->
(* create a new state and add it to the todo queue *)
let nq = State.make () in
Not_found ->
(* create a new state and add it to the todo queue *)
let nq = State.make () in
- if not (StateSet.mem q auto.bottom_states) then
+ auto.states <- StateSet.add nq auto.states;
+(* if not (StateSet.mem q auto.bottom_states) then
auto.bottom_states <- StateSet.add nq auto.bottom_states;
if not (StateSet.mem q auto.top_states) then
auto.bottom_states <- StateSet.add nq auto.bottom_states;
if not (StateSet.mem q auto.top_states) then
- auto.top_states <- StateSet.add nq auto.top_states;
+ auto.top_states <- StateSet.add nq auto.top_states; *)
Hashtbl.add memo_state (q, false) nq;
Queue.add (q, false) todo; nq
in
Hashtbl.add memo_state (q, false) nq;
Queue.add (q, false) todo; nq
in
Not_found ->
let nq = if b then q else
let nq = State.make () in
Not_found ->
let nq = if b then q else
let nq = State.make () in
- if not (StateSet.mem q auto.bottom_states) then
+ auto.states <- StateSet.add nq auto.states;
+(* if not (StateSet.mem q auto.bottom_states) then
auto.bottom_states <- StateSet.add nq auto.bottom_states;
if not (StateSet.mem q auto.top_states) then
auto.bottom_states <- StateSet.add nq auto.bottom_states;
if not (StateSet.mem q auto.top_states) then
- auto.top_states <- StateSet.add nq auto.top_states;
+ auto.top_states <- StateSet.add nq auto.top_states; *)
nq
in
Hashtbl.add memo_state key nq; nq
nq
in
Hashtbl.add memo_state key nq; nq
(***********************************************************************)
(*
(***********************************************************************)
(*
- Time-stamp: <Last modified on 2013-03-05 16:24:35 CET by Kim Nguyen>
+ Time-stamp: <Last modified on 2013-03-05 18:35:19 CET by Kim Nguyen>
let eval_trans l ctx acc =
List.fold_left (fun (acct, accs) ((q, phi) as trs) ->
let eval_trans l ctx acc =
List.fold_left (fun (acct, accs) ((q, phi) as trs) ->
+ if StateSet.mem q accs then (acct, accs) else
if Ata.SFormula.eval ctx phi then
(acct, StateSet.add q accs)
else
if Ata.SFormula.eval ctx phi then
(acct, StateSet.add q accs)
else
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 tag = T.tag tree node in
let trans0 = Ata.get_trans auto auto.Ata.states tag in
- let parent_states = if parent == T.nil then auto.Ata.top_states else get cache tree parent in
- let fc_states = if fc == T.nil then auto.Ata.bottom_states else get cache tree fc in
- let ns_states = if ns == T.nil then auto.Ata.bottom_states else get cache tree ns in
+ let parent_states = (*if parent == T.nil then auto.Ata.top_states else*) get cache tree parent in
+ let fc_states = (*if fc == T.nil then auto.Ata.bottom_states else*) get cache tree fc in
+ let ns_states = (*if ns == T.nil then auto.Ata.bottom_states else*) get cache tree ns in
+ let is_root = parent == T.nil in
let ctx0 =
if is_left then
let ctx0 =
if is_left then
- Ata.make_ctx fc_states ns_states parent_states StateSet.empty states0
+ Ata.make_ctx fc_states ns_states parent_states StateSet.empty states0 is_left is_root
- Ata.make_ctx fc_states ns_states StateSet.empty parent_states states0
+ Ata.make_ctx fc_states ns_states StateSet.empty parent_states states0 is_left is_root
- eprintf "[Iteration % 4d] node: %a, context: %a\n%!"
+ eprintf "-- [Iteration % 4d] --\n node: %a\n context: %a\n%!"
i T.print_node node Ata.print_ctx ctx0;
i T.print_node node Ata.print_ctx ctx0;
- List.iter (fun (q, phi) -> eprintf "%a -> %a\n" State.print q Ata.SFormula.print phi) trans0;
+ List.iter (fun (q, phi) -> eprintf " %a -> %a\n" State.print q Ata.SFormula.print phi) trans0;
eprintf "----------------------\n%!";
let trans1, states1 = eval_trans trans0 ctx0 StateSet.empty in
if states1 != states0 then set cache tree node states1;
eprintf "----------------------\n%!";
let trans1, states1 = eval_trans trans0 ctx0 StateSet.empty in
if states1 != states0 then set cache tree node states1;
(***********************************************************************)
(*
(***********************************************************************)
(*
- Time-stamp: <Last modified on 2013-03-05 15:24:20 CET by Kim Nguyen>
+ Time-stamp: <Last modified on 2013-03-05 19:21:37 CET by Kim Nguyen>
let ( => ) a b = (a, b)
let ( ** ) l q = mk_atom l true q
let ( => ) a b = (a, b)
let ( ** ) l q = mk_atom l true q
+let is_left = mk_atom `Is1 true State.dummy
+let is_right = mk_atom `Is2 true State.dummy
let ( ++ ) a b = Ata.SFormula.or_ a b
let ( %% ) a b = Ata.SFormula.and_ a b
let ( @: ) a b = StateSet.add a b
let ( ++ ) a b = Ata.SFormula.or_ a b
let ( %% ) a b = Ata.SFormula.and_ a b
let ( @: ) a b = StateSet.add a b
+let node_set = QNameSet.remove QName.document QNameSet.any
+let star_set = QNameSet.diff QNameSet.any (
+ List.fold_right (QNameSet.add)
+ [ QName.document; QName.text; QName.attribute_map ]
+ QNameSet.empty)
+let attribute = QNameSet.singleton QName.attribute_map
+let root_set = QNameSet.singleton QName.document
+
(* [compile_axis_test axis test q phi trans states] Takes an xpath
[axis] and node [test], a formula [phi], a list of [trans]itions
and a set of [states] and returns a formula [phi'], a new set of
(* [compile_axis_test axis test q phi trans states] Takes an xpath
[axis] and node [test], a formula [phi], a list of [trans]itions
and a set of [states] and returns a formula [phi'], a new set of
| Descendant self ->
(if self then (`Epsilon ** q) else (`Left ** q)),
(q, [ test => phi;
| Descendant self ->
(if self then (`Epsilon ** q) else (`Left ** q)),
(q, [ test => phi;
- QNameSet.any => (`Left ** q) ++ (`Right ** q) ]) :: trans,
+ QNameSet.any => (`Left ** q);
+ QNameSet.any => (`Right ** q) ]) :: trans,
states
| Parent ->
let q' = State.make () in
states
| Parent ->
let q' = State.make () in
- let move = (`Up1 ** q) ++ (`Up2 ** q') in
+ let move = (`Up1 ** q %% is_left) ++ (`Up2 ** q' %% is_right) in
move,
(q, [ test => phi ])
:: (q', [ QNameSet.any => move ]) :: trans,
move,
(q, [ test => phi ])
:: (q', [ QNameSet.any => move ]) :: trans,
| Ancestor self ->
let q' = State.make () in
| Ancestor self ->
let q' = State.make () in
- let move = (`Up1 ** q) ++ (`Up2 ** q') in
+ let move = (`Up1 ** q %% is_left) ++ (`Up2 ** q' %% is_right) in
(if self then (`Epsilon ** q) else move),
(q, [ test => phi;
(if self then (`Epsilon ** q) else move),
(q, [ test => phi;
- QNameSet.any => move ])
:: (q', [ QNameSet.any => move ]) :: trans,
(q' @: states)
:: (q', [ QNameSet.any => move ]) :: trans,
(q' @: states)
let move =
if axis = PrecedingSibling then
(`Up2 ** q)
let move =
if axis = PrecedingSibling then
(`Up2 ** q)
+ else (`Right ** q %% is_right)
in
move,
(q, [ test => phi;
in
move,
(q, [ test => phi;
- QNameSet.any => move ]) :: trans,
+ star_set => move ]) :: trans,