type 'a node = private int
type node_kind = [`Text | `Tree ]
+type t = {
+ doc : tree;
+ ttable : (Tag.t,(Ptset.Int.t*Ptset.Int.t*Ptset.Int.t*Ptset.Int.t)) Hashtbl.t;
+}
+
external inode : 'a node -> int = "%identity"
external nodei : int -> 'a node = "%identity"
let compare_node x y = (inode x) - (inode y)
external parse_xml_uri : string -> int -> bool -> bool -> tree = "caml_call_shredder_uri"
external parse_xml_string : string -> int -> bool -> bool -> tree = "caml_call_shredder_string"
-
+external tree_print_xml_fast3 : tree -> [`Tree ] node -> Unix.file_descr ->unit = "caml_xml_tree_print"
external tree_save : tree -> Unix.file_descr -> unit = "caml_xml_tree_save"
-external tree_load : Unix.file_descr -> tree = "caml_xml_tree_load"
+external tree_load : Unix.file_descr -> bool -> int -> tree = "caml_xml_tree_load"
external nullt : unit -> 'a node = "caml_xml_tree_nullt"
let nulldoc : [`Text ] node = nodei ~-1
let root : [`Tree ] node = nodei 0
-external text_get_tc_text : tree -> [`Text] node -> string = "caml_text_collection_get_text"
-
+external text_get_text : tree -> [`Text] node -> string = "caml_text_collection_get_text"
external text_is_empty : tree -> [`Text ] node -> bool = "caml_text_collection_empty_text"
let text_is_empty t n = (equal_node nulldoc n) || text_is_empty t n
+external text_is_prefix : tree -> string -> bool = "caml_text_collection_is_prefix"
+external text_is_suffix : tree -> string -> bool = "caml_text_collection_is_suffix"
+external text_is_equal : tree -> string -> bool = "caml_text_collection_is_equal"
external text_is_contains : tree -> string -> bool = "caml_text_collection_is_contains"
-external text_count_contains : tree -> string -> int = "caml_text_collection_count_contains"
-external text_count : tree -> string -> int = "caml_text_collection_count"
-external text_contains : tree -> string -> [`Text ] node array = "caml_text_collection_contains"
-external text_unsorted_contains : tree -> string -> unit = "caml_text_collection_unsorted_contains"
-external text_get_cached_text : tree -> [`Text] node -> string = "caml_text_collection_get_cached_text"
+external text_is_lessthan : tree -> string -> bool = "caml_text_collection_is_lessthan"
+
+external text_count : tree -> string -> int = "caml_text_collection_count"
+external text_count_prefix : tree -> string -> int = "caml_text_collection_count_prefix"
+external text_count_suffix : tree -> string -> int = "caml_text_collection_count_suffix"
+external text_count_equal : tree -> string -> int = "caml_text_collection_count_equal"
+external text_count_contains : tree -> string -> int = "caml_text_collection_count_contains"
+external text_count_lessthan : tree -> string -> int = "caml_text_collection_count_lessthan"
+
+external text_prefix : tree -> string -> [`Text ] node array = "caml_text_collection_prefix"
+external text_suffix : tree -> string -> [`Text ] node array = "caml_text_collection_suffix"
+external text_equals : tree -> string -> [`Text ] node array = "caml_text_collection_equals"
+external text_contains : tree -> string -> [`Text ] node array = "caml_text_collection_contains"
+external text_lessthan : tree -> string -> [`Text ] node array = "caml_text_collection_lessthan"
+
-external tree_root : tree -> [`Tree] node = "caml_xml_tree_root"
-external tree_subtree_size : tree -> [`Tree] node -> int = "caml_xml_tree_subtree_size"
-
+external tree_root : tree -> [`Tree] node = "caml_xml_tree_root" "noalloc"
+external tree_size : tree -> int = "caml_xml_tree_size" "noalloc"
+external tree_subtree_size : tree -> [`Tree] node -> int = "caml_xml_tree_subtree_size" "noalloc"
+external tree_subtree_elements : tree -> [`Tree] node -> int = "caml_xml_tree_subtree_elements" "noalloc"
+external tree_subtree_tags : tree -> [`Tree] node -> Tag.t -> int = "caml_xml_tree_subtree_elements" "noalloc"
+
let tree_is_nil x = equal_node x nil
+external tree_is_leaf : tree -> [`Tree ] node -> bool = "caml_xml_tree_is_leaf" "noalloc"
+external tree_is_ancestor : tree -> [`Tree ] node -> [`Tree ] node -> bool = "caml_xml_tree_is_ancestor" "noalloc"
+external tree_is_child : tree -> [`Tree ] node -> [`Tree ] node -> bool = "caml_xml_tree_is_child" "noalloc"
+external tree_is_first_child : tree -> [`Tree ] node -> bool = "caml_xml_tree_is_first_child" "noalloc"
+external tree_num_children : tree -> [`Tree ] node -> int = "caml_xml_tree_num_children" "noalloc"
+external tree_child_number : tree -> [`Tree ] node -> int = "caml_xml_tree_child_number" "noalloc"
+external tree_depth : tree -> [`Tree ] node -> int = "caml_xml_tree_depth" "noalloc"
+external tree_preorder : tree -> [`Tree ] node -> int = "caml_xml_tree_preorder" "noalloc"
+external tree_postorder : tree -> [`Tree ] node -> int = "caml_xml_tree_postorder" "noalloc"
+external tree_tag : tree -> [`Tree ] node -> Tag.t = "caml_xml_tree_tag" "noalloc"
+external tree_doc_ids : tree -> [`Tree ] node -> [`Text] node*[`Text] node = "caml_xml_tree_doc_ids"
external tree_parent : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_parent" "noalloc"
-external tree_parent_doc : tree -> [`Text ] node -> [`Tree ] node = "caml_xml_tree_parent_doc" "noalloc"
-(*external tree_prev_doc : tree -> [`Text ] node -> [`Tree ] node = "caml_xml_tree_prev_doc" "noalloc" *)
+external tree_child : tree -> [`Tree] node -> int -> [`Tree] node = "caml_xml_tree_child" "noalloc"
external tree_first_child : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_first_child" "noalloc"
external tree_first_element : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_first_element" "noalloc"
-external tree_tagged_child : tree -> [`Tree] node -> Tag.t -> [`Tree] node = "caml_xml_tree_tagged_child" "noalloc"
+external tree_last_child : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_last_child" "noalloc"
external tree_next_sibling : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_next_sibling" "noalloc"
external tree_next_element : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_next_element" "noalloc"
-external tree_tagged_sibling : tree -> [`Tree] node -> Tag.t -> [`Tree] node = "caml_xml_tree_tagged_sibling" "noalloc"
-
external tree_prev_sibling : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_prev_sibling" "noalloc"
-external tree_is_leaf : tree -> [`Tree] node -> bool = "caml_xml_tree_is_leaf" "noalloc"
-external tree_last_child : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_last_child" "noalloc"
-external tree_is_first_child : tree -> [`Tree] node -> bool = "caml_xml_tree_is_first_child" "noalloc"
+external tree_tagged_child : tree -> [`Tree] node -> Tag.t -> [`Tree] node = "caml_xml_tree_tagged_child" "noalloc"
+type unordered_set
+external unordered_set_alloc : int -> unordered_set = "caml_unordered_set_alloc"
+external unordered_set_length : unordered_set -> int = "caml_unordered_set_length"
+external unordered_set_insert : unordered_set -> int -> unit = "caml_unordered_set_set" "noalloc"
-external tree_tag_id : tree -> [`Tree ] node -> Tag.t = "caml_xml_tree_tag_id" "noalloc"
-
+external tree_select_child : tree -> [`Tree ] node -> unordered_set -> [`Tree] node = "caml_xml_tree_select_child" "noalloc"
+external tree_tagged_following_sibling : tree -> [`Tree] node -> Tag.t -> [`Tree] node = "caml_xml_tree_tagged_following_sibling" "noalloc"
+external tree_select_following_sibling : tree -> [`Tree ] node -> unordered_set -> [`Tree] node = "caml_xml_tree_select_following_sibling" "noalloc"
+external tree_tagged_descendant : tree -> [`Tree ] node -> Tag.t -> [`Tree ] node = "caml_xml_tree_tagged_descendant" "noalloc"
+external tree_select_descendant : tree -> [`Tree ] node -> unordered_set -> [`Tree] node = "caml_xml_tree_select_descendant" "noalloc"
+external tree_tagged_following : tree -> [`Tree ] node -> Tag.t -> [`Tree ] node = "caml_xml_tree_tagged_following" "noalloc"
+external tree_tagged_following_below : tree -> [`Tree ] node -> Tag.t -> [`Tree ] node -> [`Tree ] node = "caml_xml_tree_tagged_following_below" "noalloc"
+external tree_select_following_below : tree -> [`Tree ] node -> unordered_set -> [`Tree] node -> [`Tree] node = "caml_xml_tree_select_following_below" "noalloc"
-let tree_is_last t n = equal_node nil (tree_next_sibling t n)
-
-(*external tree_prev_text : tree -> [`Tree] node -> [`Text ] node = "caml_xml_tree_prev_text" "noalloc" *)
-external tree_my_text : tree -> [`Tree] node -> [`Text ] node = "caml_xml_tree_my_text" "noalloc"
-(*external tree_next_text : tree -> [`Tree] node -> [`Text ] node = "caml_xml_tree_next_text" "noalloc" *)
-external tree_doc_ids : tree -> [`Tree ] node -> [`Text ] node * [`Text ] node = "caml_xml_tree_doc_ids"
+external tree_tagged_following_before : tree -> [`Tree ] node -> Tag.t -> [`Tree ] node -> [`Tree ] node = "caml_xml_tree_tagged_following_before" "noalloc"
+external tree_select_following_below : tree -> [`Tree ] node -> unordered_set -> [`Tree] node -> [`Tree] node = "caml_xml_tree_select_following_before" "noalloc"
-let text_size tree = inode (snd ( tree_doc_ids tree root ))
+external tree_my_text : tree -> [`Tree ] node -> [`Text] node = "caml_xml_tree_my_text" "noalloc"
+external tree_my_text_unsafe : tree -> [`Tree ] node -> [`Text] node = "caml_xml_tree_my_text_unsafe" "noalloc"
+external tree_text_xml_id : tree -> [`Text ] node -> int = "caml_xml_tree_text_xml_id" "noalloc"
+external tree_node_xml_id : tree -> [`Tree ] node -> int = "caml_xml_tree_node_xml_id" "noalloc"
-let text_get_cached_text t (x:[`Text] node) =
- if x == nulldoc then ""
- else
- text_get_cached_text t x
+external tree_parent_node : tree -> [`Text ] node -> [`Tree ] node = "caml_xml_tree_parent_node" "noalloc"
+(*external tree_prev_doc : tree -> [`Text ] node -> [`Tree ] node = "caml_xml_tree_prev_doc" "noalloc" *)
-external tree_text_xml_id : tree -> [`Text ] node -> int = "caml_xml_tree_text_xml_id" "noalloc"
-external tree_node_xml_id : tree -> [`Tree ] node -> int = "caml_xml_tree_node_xml_id" "noalloc"
-external tree_is_ancestor : tree -> [`Tree ] node -> [`Tree ] node -> bool = "caml_xml_tree_is_ancestor" "noalloc"
-external tree_tagged_desc : tree -> [`Tree ] node -> Tag.t -> [`Tree ] node = "caml_xml_tree_tagged_desc" "noalloc"
-external tree_tagged_foll_below : tree -> [`Tree ] node -> Tag.t -> [`Tree ] node -> [`Tree ] node = "caml_xml_tree_tagged_foll_below" "noalloc"
-external tree_subtree_tags : tree -> [`Tree ] node -> Tag.t -> int = "caml_xml_tree_subtree_tags" "noalloc"
+external tree_closing : tree -> [`Tree] node -> [`Tree] node = "caml_xml_tree_closing" "noalloc"
+external tree_is_open : tree -> [`Tree] node -> bool = "caml_xml_tree_is_open" "noalloc"
-type unordered_set
-external unordered_set_alloc : int -> unordered_set = "caml_unordered_set_alloc"
-external unordered_set_length : unordered_set -> int = "caml_unordered_set_length"
-external unordered_set_insert : unordered_set -> int -> unit = "caml_unordered_set_set" "noalloc"
+external benchmark_jump : tree -> Tag.t -> unit = "caml_benchmark_jump" "noalloc"
+
+let benchmark_jump t s = benchmark_jump t.doc s
+
+external benchmark_fcns : tree -> unit = "caml_benchmark_fcns" "noalloc"
+
+let benchmark_fcns t = benchmark_fcns t.doc
+
+external benchmark_lcps : tree -> unit = "caml_benchmark_lcps" "noalloc"
+
+let benchmark_lcps t = benchmark_lcps t.doc
+
+
+
+
+
+
+
+let text_size tree = inode (snd ( tree_doc_ids tree root ))
+
+let text_get_text t (x:[`Text] node) =
+ if x == nulldoc then ""
+ else text_get_text t x
+
-external tree_select_child : tree -> [`Tree ] node -> unordered_set -> [`Tree] node = "caml_xml_tree_select_child" "noalloc"
-external tree_select_foll_sibling : tree -> [`Tree ] node -> unordered_set -> [`Tree] node = "caml_xml_tree_select_foll_sibling" "noalloc"
-external tree_select_desc : tree -> [`Tree ] node -> unordered_set -> [`Tree] node = "caml_xml_tree_select_desc" "noalloc"
-external tree_select_foll_below : tree -> [`Tree ] node -> unordered_set -> [`Tree] node -> [`Tree] node = "caml_xml_tree_select_foll_below" "noalloc"
module HPtset = Hashtbl.Make(Ptset.Int)
HPtset.add vector_htbl s v; v
-type t = {
- doc : tree;
- ttable : (Tag.t,(Ptset.Int.t*Ptset.Int.t*Ptset.Int.t*Ptset.Int.t)) Hashtbl.t;
-}
+
let subtree_size t i = tree_subtree_size t.doc i
+let subtree_elements t i = tree_subtree_elements t.doc i
let text_size t = text_size t.doc
module MemUnion = Hashtbl.Make (struct
type t = Ptset.Int.t*Ptset.Int.t
- let equal (x,y) (z,t) = (Ptset.Int.equal x z)&&(Ptset.Int.equal y t)
+ let equal (x,y) (z,t) = x == z || y == t
let equal a b = equal a b || equal b a
let hash (x,y) = (* commutative hash *)
- let x = Ptset.Int.hash x
- and y = Ptset.Int.hash y
+ let x = Ptset.Int.uid x
+ and y = Ptset.Int.uid y
in
- if x < y then HASHINT2(x,y) else HASHINT2(y,x)
+ if x <= y then HASHINT2(x,y) else HASHINT2(y,x)
end)
module MemAdd = Hashtbl.Make (
struct
type t = Tag.t*Ptset.Int.t
- let equal (x,y) (z,t) = (x == z)&&(Ptset.Int.equal y t)
- let hash (x,y) = HASHINT2(x,Ptset.Int.hash y)
+ let equal (x,y) (z,t) = (x == z)&&(y == t)
+ let hash (x,y) = HASHINT2(x,Ptset.Int.uid y)
end)
+module MemUpdate = struct
+include Hashtbl.Make (
+ struct
+ type t = Tag.t*Ptset.Int.t*Ptset.Int.t*Ptset.Int.t*Ptset.Int.t
+ let equal (a1,b1,c1,d1,e1) (a2,b2,c2,d2,e2) = a1==a2 &&
+ b1 == b2 && c1 == c2 && d1 == d2 && e1 == e2
+ let hash (a,b,c,d,e) = HASHINT4(HASHINT2(a,Ptset.Int.uid b),Ptset.Int.uid c,Ptset.Int.uid d,Ptset.Int.uid e)
+ end)
+
+end
+
let collect_tags tree =
+ let _ = Printf.eprintf "Collecting Tags\n%!" in
let h_union = MemUnion.create BIG_H_SIZE in
let pt_cup s1 s2 =
try
with
| Not_found -> let r = Ptset.Int.add t s in
MemAdd.add h_add (t,s) r;r
- in
+ in
let h = Hashtbl.create BIG_H_SIZE in
- let update t sc sb ss sa =
+ let update t sc sb ss sa =
let schild,sbelow,ssibling,safter =
try
Hashtbl.find h t
(Ptset.Int.empty,Ptset.Int.empty,Ptset.Int.empty,Ptset.Int.empty)
in
Hashtbl.replace h t
- (pt_cup sc schild,pt_cup sbelow sb, pt_cup ssibling ss, pt_cup safter sa)
+ (pt_cup sc schild,pt_cup sbelow sb, pt_cup ssibling ss, pt_cup safter sa)
in
- let rec loop_right id acc_sibling acc_after=
+ let rec loop right id acc_after =
if id == nil
- then (acc_sibling,acc_after)
- else
- let sibling2,after2 = loop_right (tree_next_sibling tree id) acc_sibling acc_after in
- let child1,below1 = loop_left (tree_first_child tree id) after2 in
- let tag = tree_tag_id tree id in
- update tag child1 below1 sibling2 after2;
- (pt_add tag sibling2, (pt_add tag (pt_cup after2 below1)))
- and loop_left id acc_after =
- if id == nil
- then (Ptset.Int.empty,Ptset.Int.empty)
- else
- let sibling2,after2 = loop_right (tree_next_sibling tree id) Ptset.Int.empty acc_after in
- let child1,below1 = loop_left (tree_first_child tree id) after2 in
- let tag = tree_tag_id tree id in
- update tag child1 below1 sibling2 after2;
- (pt_add tag sibling2,(pt_add tag (pt_cup after2 below1)))
+ then Ptset.Int.empty,Ptset.Int.empty,acc_after else
+ let sibling2,desc2,after2 = loop true (tree_next_sibling tree id) acc_after in
+ let child1,desc1,after1 = loop false (tree_first_child tree id) after2 in
+ let tag = tree_tag tree id in
+ update tag child1 desc1 sibling2 after2;
+ ( pt_add tag sibling2,
+ pt_add tag (pt_cup desc1 desc2),
+ if right then pt_cup after1 (pt_cup desc1 desc2) else acc_after )
in
- let _ = loop_left (tree_root tree) Ptset.Int.empty in h
-
-
-
+ let _ = loop false (tree_root tree) Ptset.Int.empty in
+ let _ = Printf.eprintf "Finished\n%!" in
+ h
+
+
+
let contains_array = ref [| |]
let contains_index = Hashtbl.create 4096
with
Not_found -> false
-let init_contains t s =
- let a = text_contains t.doc s
+let init_textfun f t s =
+ let a = match f with
+ | `CONTAINS -> text_contains t.doc s
+ | `STARTSWITH -> text_prefix t.doc s
+ | `ENDSWITH -> text_suffix t.doc s
+ | `EQUALS -> text_equals t.doc s
in
- Array.fast_sort (compare) a;
+ (*Array.fast_sort (compare) a; *)
contains_array := a;
Array.iter (fun x -> Hashtbl.add contains_index x true) !contains_array
let count_contains t s = text_count_contains t.doc s
-let unsorted_contains t s = text_unsorted_contains t.doc s
let init_naive_contains t s =
let i,j = tree_doc_ids t.doc (tree_root t.doc)
let rec loop n acc l =
if n >= j then acc,l
else
- let s = text_get_cached_text t.doc n
+ let s = text_get_text t.doc n
in
if matching s
then loop (nodei ((inode n)+1)) (n::acc) (l+1)
let l = Array.length !contains_array in
let i,j = tree_doc_ids tree.doc t in
let id = if l == 0 then i else (array_find !contains_array i j) in
- tree_parent_doc tree.doc id
+ tree_parent_node tree.doc id
let text_next tree t root =
let l = Array.length !contains_array in
let id = if l == 0 then if inf > j then nulldoc else inf
else array_find !contains_array inf j
in
- tree_parent_doc tree.doc id
+ tree_parent_node tree.doc id
let node_of_t t =
let _ = Tag.init (Obj.magic t) in
let table = collect_tags t
+ in (*
+ let _ = Hashtbl.iter (fun t (c,d,ns,f) ->
+ Printf.eprintf "Tag %s has:\n" (Tag.to_string t);
+ Printf.eprintf "Child tags: ";
+ Ptset.Int.iter (fun t -> Printf.eprintf "%s "(Tag.to_string t)) c;
+ Printf.eprintf "\nDescendant tags: ";
+ Ptset.Int.iter (fun t -> Printf.eprintf "%s "(Tag.to_string t)) d;
+ Printf.eprintf "\nNextSibling tags: ";
+ Ptset.Int.iter (fun t -> Printf.eprintf "%s "(Tag.to_string t)) ns;
+ Printf.eprintf "\nFollowing tags: ";
+ Ptset.Int.iter (fun t -> Printf.eprintf "%s "(Tag.to_string t)) f;
+ Printf.eprintf "\n\n%!";) table
in
+
+ *)
{ doc= t;
ttable = table;
}
let parse_xml_uri str = parse parse_xml_uri str
let parse_xml_string str = parse parse_xml_string str
+let size t = tree_size t.doc;;
external pool : tree -> Tag.pool = "%identity"
let magic_string = "SXSI_INDEX"
-let version_string = "1"
+let version_string = "2"
let pos fd =
Unix.lseek fd 0 Unix.SEEK_CUR
close_out out_c
;;
-let load ?(sample=64) str =
+let load ?(sample=64) ?(load_text=true) str =
let fd = Unix.openfile str [ Unix.O_RDONLY ] 0o644 in
let in_c = Unix.in_channel_of_descr fd in
let _ = set_binary_mode_in in_c true in
let _ = Printf.eprintf "\nLoading tag table : " in
let ntable = time (load_table) () in
ignore(Unix.lseek fd (pos_in in_c) Unix.SEEK_SET);
- let tree = { doc = tree_load fd;
+ let tree = { doc = tree_load fd load_text sample;
ttable = ntable;}
in close_in in_c;
tree
let is_left t n = tree_is_first_child t.doc n
+
+
let is_below_right t n1 n2 =
tree_is_ancestor t.doc (tree_parent t.doc n1) n2
&& not (tree_is_ancestor t.doc n1 n2)
+
+let is_binary_ancestor t n1 n2 =
+ let p = tree_parent t.doc n1 in
+ let fin = tree_closing t.doc p in
+ n2 > n1 && n2 < fin
+(* (is_below_right t n1 n2) ||
+ (tree_is_ancestor t.doc n1 n2) *)
let parent t n = tree_parent t.doc n
-let first_child t = (); fun n -> tree_first_child t.doc n
-let first_element t = (); fun n -> tree_first_element t.doc n
+let first_child t = let doc = t.doc in ();fun n -> tree_first_child doc n
+let first_element t = let doc = t.doc in (); fun n -> tree_first_element doc n
(* these function will be called in two times: first partial application
on the tag, then application of the tag and the tree, then application of
let v = ptset_to_vector ts in ();
fun n -> tree_select_child t.doc n v
-let next_sibling t = (); fun n -> tree_next_sibling t.doc n
-let next_element t = (); fun n -> tree_next_element t.doc n
+let next_sibling t = let doc = t.doc in (); fun n -> tree_next_sibling doc n
+let next_element t = let doc = t.doc in (); fun n -> tree_next_element doc n
-let tagged_sibling t tag = (); fun n -> tree_tagged_sibling t.doc n tag
+let tagged_following_sibling t tag = (); fun n -> tree_tagged_following_sibling t.doc n tag
-let select_sibling t = fun ts ->
+let select_following_sibling t = fun ts ->
let v = (ptset_to_vector ts) in ();
- fun n -> tree_select_foll_sibling t.doc n v
+ fun n -> tree_select_following_sibling t.doc n v
-let next_sibling_ctx t = (); fun n _ -> tree_next_sibling t.doc n
-let next_element_ctx t = (); fun n _ -> tree_next_element t.doc n
-let tagged_sibling_ctx t tag = (); fun n _ -> tree_tagged_sibling t.doc n tag
+let next_sibling_below t = (); fun n _ -> tree_next_sibling t.doc n
+let next_element_below t = (); fun n _ -> tree_next_element t.doc n
+let tagged_following_sibling_below t tag = (); fun n _ -> tree_tagged_following_sibling t.doc n tag
-let select_sibling_ctx t = fun ts ->
+let select_following_sibling_below t = fun ts ->
let v = (ptset_to_vector ts) in ();
- fun n _ -> tree_select_foll_sibling t.doc n v
+ fun n _ -> tree_select_following_sibling t.doc n v
let id t n = tree_node_xml_id t.doc n
-let tag t n = if n == nil then Tag.nullt else tree_tag_id t.doc n
+let tag t n = if n == nil then Tag.nullt else tree_tag t.doc n
-let tagged_desc t tag = (); fun n -> tree_tagged_desc t.doc n tag
+let tagged_descendant t tag =
+ let doc = t.doc in (); fun n -> tree_tagged_descendant doc n tag
-let select_desc t = fun ts ->
+let select_descendant t = fun ts ->
let v = (ptset_to_vector ts) in ();
- fun n -> tree_select_desc t.doc n v
+ fun n -> tree_select_descendant t.doc n v
-let tagged_foll_ctx t tag = (); fun n ctx -> tree_tagged_foll_below t.doc n tag ctx
+let tagged_following_below t tag =
+ let doc = t.doc in
+ (); fun n ctx -> tree_tagged_following_below doc n tag ctx
-let select_foll_ctx t = fun ts ->
+let select_following_below t = fun ts ->
let v = (ptset_to_vector ts) in ();
- fun n ctx -> tree_select_foll_below t.doc n v ctx
+ fun n ctx -> tree_select_following_below t.doc n v ctx
+
+let closing t n = tree_closing t.doc n
+let is_open t n = tree_is_open t.doc n
+let get_text_id t n = tree_my_text t.doc n
let last_idx = ref 0
let array_find a i j =
let count t s = text_count t.doc s
-
- let print_xml_fast outc tree t =
+ let stack = ref []
+ let init_stack () = stack := []
+ let push x = stack:= x::!stack
+ let peek () = match !stack with
+ p::_ -> p
+ | _ -> failwith "peek"
+ let pop () = match !stack with
+ p::r -> stack:=r; p
+ | _ -> failwith "pop"
+
+ let next t = nodei ( (inode t) + 1 )
+ let next2 t = nodei ( (inode t) + 2 )
+ let next3 t = nodei ( (inode t) + 3 )
+
+ let print_xml_fast2 =
+ let _ = init_stack () in
+ let h = Hashtbl.create MED_H_SIZE in
+ let tag_str t = try Hashtbl.find h t with
+ Not_found -> let s = Tag.to_string t in
+ Hashtbl.add h t s;s
+ in
+ let h_att = Hashtbl.create MED_H_SIZE in
+ let att_str t = try Hashtbl.find h_att t with
+ Not_found -> let s = Tag.to_string t in
+ let attname = String.sub s 3 ((String.length s) -3) in
+ Hashtbl.add h_att t attname;attname
+ in fun outc tree t ->
+ let tree = tree.doc in
+ let fin = tree_closing tree t in
+ let rec loop_tag t tag =
+ if t <= fin then
+ if tree_is_open tree t then
+ (* opening tag *)
+ if tag == Tag.pcdata then
+ begin
+ output_string outc (text_get_text tree (tree_my_text_unsafe tree t));
+ loop (next2 t) (* skip closing $ *)
+ end
+ else
+ let tagstr = tag_str tag in
+ let _ = output_char outc '<';
+ output_string outc tagstr in
+ let t' = next t in
+ if tree_is_open tree t' then
+ let _ = push tagstr in
+ let tag' = tree_tag tree t' in
+ if tag' == Tag.attribute then let t'' = loop_attr (next t') 0 in
+ output_string outc ">"; loop t'' else (output_string outc ">";loop_tag t' tag')
+ else (* closing with no content *)
+ let _ = output_string outc "/>" in
+ loop (next t')
+ else
+ begin
+ (* closing tag *)
+ output_string outc "</";
+ output_string outc (pop());
+ output_char outc '>';
+ loop (next t);
+ end
+ and loop t = loop_tag t (tree_tag tree t)
+ and loop_attr t n =
+ if tree_is_open tree t then
+ let attname = att_str (tree_tag tree t) in
+ output_char outc ' ';
+ output_string outc attname;
+ output_string outc "=\"";
+ let t = next t in (* open $@ *)
+ output_string outc (text_get_text tree (tree_my_text_unsafe tree t));
+ output_char outc '"';
+ loop_attr (next3 t) (n+1)
+ else
+ next t (* close @ *)
+ in loop t
+
+ let print_xml_fast =
+ let h = Hashtbl.create MED_H_SIZE in
+ let tag_str t = try Hashtbl.find h t with
+ Not_found -> let s = Tag.to_string t in
+ Hashtbl.add h t s;s
+ in
+ let h_att = Hashtbl.create MED_H_SIZE in
+ let att_str t = try Hashtbl.find h_att t with
+ Not_found -> let s = Tag.to_string t in
+ let attname = String.sub s 3 ((String.length s) -3) in
+ Hashtbl.add h_att t attname;attname
+ in fun outc tree t ->
let rec loop ?(print_right=true) t =
if t != nil
then
- let tagid = tree_tag_id tree.doc t in
+ let tagid = tree_tag tree.doc t in
if tagid==Tag.pcdata
then
begin
- let tid = tree_my_text tree.doc t in
- output_string outc (text_get_cached_text tree.doc tid);
+ let tid = tree_my_text_unsafe tree.doc t in
+ output_string outc (text_get_text tree.doc tid);
if print_right
then loop (next_sibling tree t);
end
else
- let tagstr = Tag.to_string tagid in
+ let tagstr = tag_str tagid in
let l = first_child tree t
and r = next_sibling tree t
in
output_char outc '<';
- output_string outc tagstr;
+ output_string outc tagstr;
if l == nil then output_string outc "/>"
else
if (tag tree l) == Tag.attribute then
and loop_attributes a =
if a != nil
then
- let s = (Tag.to_string (tag tree a)) in
- let attname = String.sub s 3 ((String.length s) -3) in
+ let attname = att_str (tag tree a) in
let fsa = first_child tree a in
- let tid = tree_my_text tree.doc fsa in
+ let tid = tree_my_text_unsafe tree.doc fsa in
output_char outc ' ';
output_string outc attname;
output_string outc "=\"";
- output_string outc (text_get_cached_text tree.doc tid);
+ output_string outc (text_get_text tree.doc tid);
output_char outc '"';
loop_attributes (next_sibling tree a)
in
if tree_is_first_child t.doc n
then tree_parent t.doc n
else tree_prev_sibling t.doc n
- in if tree_tag_id t.doc r = Tag.pcdata then
+ in if tree_tag t.doc r = Tag.pcdata then
binary_parent t r
else r
let get_text t n =
let tid = tree_my_text t.doc n in
if tid == nulldoc then "" else
- text_get_cached_text t.doc tid
+ text_get_text t.doc tid
let dump_tree fmt tree =
let rec loop t n =
if t != nil then
- let tag = (tree_tag_id tree.doc t ) in
+ let tag = (tree_tag tree.doc t ) in
let tagstr = Tag.to_string tag in
let tab = String.make n ' ' in
if tag == Tag.pcdata || tag == Tag.attribute_data
then
Format.fprintf fmt "%s<%s>%s</%s>\n"
- tab tagstr (text_get_cached_text tree.doc (tree_my_text tree.doc t)) tagstr
+ tab tagstr (text_get_text tree.doc (tree_my_text tree.doc t)) tagstr
else begin
Format.fprintf fmt "%s<%s>\n" tab tagstr;
loop (tree_first_child tree.doc t) (n+2);
;;
+let print_xml_fast3 t = tree_print_xml_fast3 t.doc
+
+
+
+
+let stats t =
+ let tree = t.doc in
+ let rec loop left node acc_d total_d num_leaves =
+ if node == nil then
+ (acc_d+total_d,if left then num_leaves+1 else num_leaves)
+ else
+ let d,td = loop true (tree_first_child tree node) (acc_d+1) total_d num_leaves in
+ loop false (tree_next_sibling tree node) (acc_d) d td
+ in
+ let a,b = loop true root 0 0 0
+ in
+ Printf.eprintf "Average depth: %f, number of leaves %i\n%!" ((float_of_int a)/. (float_of_int b)) b
+;;
+
+
+
+
+
+