ocaml/camlp4/ocaml_src/lib/gramext.ml

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(* camlp4r *)
(***********************************************************************)
(* *)
(* Camlp4 *)
(* *)
(* Daniel de Rauglaudre, projet Cristal, INRIA Rocquencourt *)
(* *)
(* Copyright 2001 Institut National de Recherche en Informatique et *)
(* Automatique. Distributed only by permission. *)
(* *)
(***********************************************************************)
(* This file has been generated by program: do not edit! *)
type grammar =
{ gtokens : (Token.pattern, int ref) Hashtbl.t;
mutable glexer : Token.lexer }
;;
type g_entry =
{ egram : grammar;
ename : string;
mutable estart : int -> Token.t Stream.t -> Obj.t;
mutable econtinue : int -> int -> Obj.t -> Token.t Stream.t -> Obj.t;
mutable edesc : g_desc }
and g_desc = Dlevels of g_level list | Dparser of (Token.t Stream.t -> Obj.t)
and g_level =
{ assoc : g_assoc;
lname : string option;
lsuffix : g_tree;
lprefix : g_tree }
and g_assoc = NonA | RightA | LeftA
and g_symbol =
Snterm of g_entry
| Snterml of g_entry * string
| Slist0 of g_symbol
| Slist0sep of g_symbol * g_symbol
| Slist1 of g_symbol
| Slist1sep of g_symbol * g_symbol
| Sopt of g_symbol
| Sself
| Snext
| Stoken of Token.pattern
| Stree of g_tree
and g_action = Obj.t
and g_tree = Node of g_node | LocAct of g_action * g_action list | DeadEnd
and g_node = { node : g_symbol; son : g_tree; brother : g_tree }
;;
type position =
First | Last | Before of string | After of string | Level of string
;;
let warning_verbose = ref true;;
let rec derive_eps =
function
Slist0 _ -> true
| Slist0sep (_, _) -> true
| Sopt _ -> true
| Stree t -> tree_derive_eps t
| _ -> false
and tree_derive_eps =
function
LocAct (_, _) -> true
| Node {node = s; brother = bro; son = son} ->
derive_eps s && tree_derive_eps son || tree_derive_eps bro
| _ -> false
;;
let rec eq_symbol s1 s2 =
match s1, s2 with
Snterm e1, Snterm e2 -> e1 == e2
| Snterml (e1, l1), Snterml (e2, l2) -> e1 == e2 && l1 = l2
| Slist0 s1, Slist0 s2 -> eq_symbol s1 s2
| Slist0sep (s1, sep1), Slist0sep (s2, sep2) ->
eq_symbol s1 s2 && eq_symbol sep1 sep2
| Slist1 s1, Slist1 s2 -> eq_symbol s1 s2
| Slist1sep (s1, sep1), Slist1sep (s2, sep2) ->
eq_symbol s1 s2 && eq_symbol sep1 sep2
| Sopt s1, Sopt s2 -> eq_symbol s1 s2
| Stree _, Stree _ -> false
| _ -> s1 = s2
;;
let is_before s1 s2 =
match s1, s2 with
Stoken ("ANY", _), _ -> false
| _, Stoken ("ANY", _) -> true
| Stoken (_, s), Stoken (_, "") when s <> "" -> true
| Stoken _, Stoken _ -> false
| Stoken _, _ -> true
| _ -> false
;;
let insert_tree gsymbols action tree =
let rec insert symbols tree =
match symbols with
s :: sl -> insert_in_tree s sl tree
| [] ->
match tree with
Node {node = s; son = son; brother = bro} ->
Node {node = s; son = son; brother = insert [] bro}
| LocAct (old_action, action_list) ->
if !warning_verbose then
begin
Printf.eprintf
"<W> Grammar extension: some rule has been masked\n";
flush stderr
end;
LocAct (action, (old_action :: action_list))
| DeadEnd -> LocAct (action, [])
and insert_in_tree s sl tree =
match try_insert s sl tree with
Some t -> t
| None -> Node {node = s; son = insert sl DeadEnd; brother = tree}
and try_insert s sl tree =
match tree with
Node {node = s1; son = son; brother = bro} ->
if eq_symbol s s1 then
let t = Node {node = s1; son = insert sl son; brother = bro} in
Some t
else if is_before s1 s || derive_eps s && not (derive_eps s1) then
let bro =
match try_insert s sl bro with
Some bro -> bro
| None -> Node {node = s; son = insert sl DeadEnd; brother = bro}
in
let t = Node {node = s1; son = son; brother = bro} in Some t
else
begin match try_insert s sl bro with
Some bro ->
let t = Node {node = s1; son = son; brother = bro} in Some t
| None -> None
end
| _ -> None
and insert_new =
function
s :: sl -> Node {node = s; son = insert_new sl; brother = DeadEnd}
| [] -> LocAct (action, [])
in
insert gsymbols tree
;;
let srules rl =
let t =
List.fold_left
(fun tree (symbols, action) -> insert_tree symbols action tree) DeadEnd
rl
in
Stree t
;;
external action : 'a -> g_action = "%identity";;
let is_level_labelled n lev =
match lev.lname with
Some n1 -> n = n1
| None -> false
;;
let insert_level e1 symbols action slev =
match e1 with
true ->
{assoc = slev.assoc; lname = slev.lname;
lsuffix = insert_tree symbols action slev.lsuffix;
lprefix = slev.lprefix}
| false ->
{assoc = slev.assoc; lname = slev.lname; lsuffix = slev.lsuffix;
lprefix = insert_tree symbols action slev.lprefix}
;;
let empty_lev lname assoc =
let assoc =
match assoc with
Some a -> a
| None -> LeftA
in
{assoc = assoc; lname = lname; lsuffix = DeadEnd; lprefix = DeadEnd}
;;
let change_lev lev n lname assoc =
let a =
match assoc with
None -> lev.assoc
| Some a ->
if a <> lev.assoc && !warning_verbose then
begin
Printf.eprintf "<W> Changing associativity of level \"%s\"\n" n;
flush stderr
end;
a
in
begin match lname with
Some n ->
if lname <> lev.lname && !warning_verbose then
begin
Printf.eprintf "<W> Level label \"%s\" ignored\n" n; flush stderr
end
| _ -> ()
end;
{assoc = a; lname = lev.lname; lsuffix = lev.lsuffix; lprefix = lev.lprefix}
;;
let get_level entry position levs =
match position with
Some First -> [], empty_lev, levs
| Some Last -> levs, empty_lev, []
| Some (Level n) ->
let rec get =
function
[] ->
Printf.eprintf "No level labelled \"%s\" in entry \"%s\"\n" n
entry.ename;
flush stderr;
failwith "Grammar.extend"
| lev :: levs ->
if is_level_labelled n lev then [], change_lev lev n, levs
else
let (levs1, rlev, levs2) = get levs in lev :: levs1, rlev, levs2
in
get levs
| Some (Before n) ->
let rec get =
function
[] ->
Printf.eprintf "No level labelled \"%s\" in entry \"%s\"\n" n
entry.ename;
flush stderr;
failwith "Grammar.extend"
| lev :: levs ->
if is_level_labelled n lev then [], empty_lev, lev :: levs
else
let (levs1, rlev, levs2) = get levs in lev :: levs1, rlev, levs2
in
get levs
| Some (After n) ->
let rec get =
function
[] ->
Printf.eprintf "No level labelled \"%s\" in entry \"%s\"\n" n
entry.ename;
flush stderr;
failwith "Grammar.extend"
| lev :: levs ->
if is_level_labelled n lev then [lev], empty_lev, levs
else
let (levs1, rlev, levs2) = get levs in lev :: levs1, rlev, levs2
in
get levs
| None ->
match levs with
lev :: levs -> [], change_lev lev "<top>", levs
| [] -> [], empty_lev, []
;;
let rec check_gram entry =
function
Snterm e ->
if e.egram != entry.egram then
begin
Printf.eprintf "\
Error: entries \"%s\" and \"%s\" do not belong to the same grammar.\n"
entry.ename e.ename;
flush stderr;
failwith "Grammar.extend error"
end
| Snterml (e, _) ->
if e.egram != entry.egram then
begin
Printf.eprintf "\
Error: entries \"%s\" and \"%s\" do not belong to the same grammar.\n"
entry.ename e.ename;
flush stderr;
failwith "Grammar.extend error"
end
| Slist0sep (s, t) -> check_gram entry t; check_gram entry s
| Slist1sep (s, t) -> check_gram entry t; check_gram entry s
| Slist0 s -> check_gram entry s
| Slist1 s -> check_gram entry s
| Sopt s -> check_gram entry s
| Stree t -> tree_check_gram entry t
| _ -> ()
and tree_check_gram entry =
function
Node {node = n; brother = bro; son = son} ->
check_gram entry n; tree_check_gram entry bro; tree_check_gram entry son
| _ -> ()
;;
let change_to_self entry =
function
Snterm e when e == entry -> Sself
| x -> x
;;
let get_initial entry =
function
Sself :: symbols -> true, symbols
| symbols -> false, symbols
;;
let insert_tokens gram symbols =
let rec insert =
function
Slist0 s -> insert s
| Slist1 s -> insert s
| Slist0sep (s, t) -> insert s; insert t
| Slist1sep (s, t) -> insert s; insert t
| Sopt s -> insert s
| Stree t -> tinsert t
| Stoken ("ANY", _) -> ()
| Stoken tok ->
gram.glexer.Token.using tok;
let r =
try Hashtbl.find gram.gtokens tok with
Not_found -> let r = ref 0 in Hashtbl.add gram.gtokens tok r; r
in
incr r
| _ -> ()
and tinsert =
function
Node {node = s; brother = bro; son = son} ->
insert s; tinsert bro; tinsert son
| _ -> ()
in
List.iter insert symbols
;;
let levels_of_rules entry position rules =
let elev =
match entry.edesc with
Dlevels elev -> elev
| Dparser _ ->
Printf.eprintf "Error: entry not extensible: \"%s\"\n" entry.ename;
flush stderr;
failwith "Grammar.extend"
in
if rules = [] then elev
else
let (levs1, make_lev, levs2) = get_level entry position elev in
let (levs, _) =
List.fold_left
(fun (levs, make_lev) (lname, assoc, level) ->
let lev = make_lev lname assoc in
let lev =
List.fold_left
(fun lev (symbols, action) ->
let symbols = List.map (change_to_self entry) symbols in
List.iter (check_gram entry) symbols;
let (e1, symbols) = get_initial entry symbols in
insert_tokens entry.egram symbols;
insert_level e1 symbols action lev)
lev level
in
lev :: levs, empty_lev)
([], make_lev) rules
in
levs1 @ List.rev levs @ levs2
;;
let logically_eq_symbols entry =
let rec eq_symbols s1 s2 =
match s1, s2 with
Snterm e1, Snterm e2 -> e1.ename = e2.ename
| Snterm e1, Sself -> e1.ename = entry.ename
| Sself, Snterm e2 -> entry.ename = e2.ename
| Snterml (e1, l1), Snterml (e2, l2) -> e1.ename = e2.ename && l1 = l2
| Slist0 s1, Slist0 s2 -> eq_symbols s1 s2
| Slist0sep (s1, sep1), Slist0sep (s2, sep2) ->
eq_symbols s1 s2 && eq_symbols sep1 sep2
| Slist1 s1, Slist1 s2 -> eq_symbols s1 s2
| Slist1sep (s1, sep1), Slist1sep (s2, sep2) ->
eq_symbols s1 s2 && eq_symbols sep1 sep2
| Sopt s1, Sopt s2 -> eq_symbols s1 s2
| Stree t1, Stree t2 -> eq_trees t1 t2
| _ -> s1 = s2
and eq_trees t1 t2 =
match t1, t2 with
Node n1, Node n2 ->
eq_symbols n1.node n2.node && eq_trees n1.son n2.son &&
eq_trees n1.brother n2.brother
| (LocAct (_, _) | DeadEnd), (LocAct (_, _) | DeadEnd) -> true
| _ -> false
in
eq_symbols
;;
(* [delete_rule_in_tree] returns
[Some (dsl, t)] if success
[dsl] =
Some (list of deleted nodes) if branch deleted
None if action replaced by previous version of action
[t] = remaining tree
[None] if failure *)
let delete_rule_in_tree entry =
let rec delete_in_tree symbols tree =
match symbols, tree with
s :: sl, Node n ->
if logically_eq_symbols entry s n.node then delete_son sl n
else
begin match delete_in_tree symbols n.brother with
Some (dsl, t) ->
Some (dsl, Node {node = n.node; son = n.son; brother = t})
| None -> None
end
| s :: sl, _ -> None
| [], Node n ->
begin match delete_in_tree [] n.brother with
Some (dsl, t) ->
Some (dsl, Node {node = n.node; son = n.son; brother = t})
| None -> None
end
| [], DeadEnd -> None
| [], LocAct (_, []) -> Some (Some [], DeadEnd)
| [], LocAct (_, (action :: list)) -> Some (None, LocAct (action, list))
and delete_son sl n =
match delete_in_tree sl n.son with
Some (Some dsl, DeadEnd) -> Some (Some (n.node :: dsl), n.brother)
| Some (Some dsl, t) ->
let t = Node {node = n.node; son = t; brother = n.brother} in
Some (Some (n.node :: dsl), t)
| Some (None, t) ->
let t = Node {node = n.node; son = t; brother = n.brother} in
Some (None, t)
| None -> None
in
delete_in_tree
;;
let rec decr_keyw_use gram =
function
Stoken tok ->
let r = Hashtbl.find gram.gtokens tok in
decr r;
if !r == 0 then
begin
Hashtbl.remove gram.gtokens tok; gram.glexer.Token.removing tok
end
| Slist0 s -> decr_keyw_use gram s
| Slist1 s -> decr_keyw_use gram s
| Slist0sep (s1, s2) -> decr_keyw_use gram s1; decr_keyw_use gram s2
| Slist1sep (s1, s2) -> decr_keyw_use gram s1; decr_keyw_use gram s2
| Sopt s -> decr_keyw_use gram s
| Stree t -> decr_keyw_use_in_tree gram t
| _ -> ()
and decr_keyw_use_in_tree gram =
function
DeadEnd | LocAct (_, _) -> ()
| Node n ->
decr_keyw_use gram n.node;
decr_keyw_use_in_tree gram n.son;
decr_keyw_use_in_tree gram n.brother
;;
let rec delete_rule_in_suffix entry symbols =
function
lev :: levs ->
begin match delete_rule_in_tree entry symbols lev.lsuffix with
Some (dsl, t) ->
begin match dsl with
Some dsl -> List.iter (decr_keyw_use entry.egram) dsl
| None -> ()
end;
begin match t with
DeadEnd when lev.lprefix == DeadEnd -> levs
| _ ->
let lev =
{assoc = lev.assoc; lname = lev.lname; lsuffix = t;
lprefix = lev.lprefix}
in
lev :: levs
end
| None ->
let levs = delete_rule_in_suffix entry symbols levs in lev :: levs
end
| [] -> raise Not_found
;;
let rec delete_rule_in_prefix entry symbols =
function
lev :: levs ->
begin match delete_rule_in_tree entry symbols lev.lprefix with
Some (dsl, t) ->
begin match dsl with
Some dsl -> List.iter (decr_keyw_use entry.egram) dsl
| None -> ()
end;
begin match t with
DeadEnd when lev.lsuffix == DeadEnd -> levs
| _ ->
let lev =
{assoc = lev.assoc; lname = lev.lname; lsuffix = lev.lsuffix;
lprefix = t}
in
lev :: levs
end
| None ->
let levs = delete_rule_in_prefix entry symbols levs in lev :: levs
end
| [] -> raise Not_found
;;
let rec delete_rule_in_level_list entry symbols levs =
match symbols with
Sself :: symbols -> delete_rule_in_suffix entry symbols levs
| Snterm e :: symbols when e == entry ->
delete_rule_in_suffix entry symbols levs
| _ -> delete_rule_in_prefix entry symbols levs
;;