parser.ml 10.6 KB
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open Location
open Ast

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(* let ()  = Grammar.error_verbose := true *)
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let gram    = Grammar.gcreate (Lexer.gmake ())
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let gram    = Grammar.gcreate (Wlexer.lexer Wlexer.token Wlexer.latin1_engine)


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let prog    = Grammar.Entry.create gram "prog"
let expr    = Grammar.Entry.create gram "expression"
let pat     = Grammar.Entry.create gram "type/pattern expression"
let regexp  = Grammar.Entry.create gram "type/pattern regexp"
let const   = Grammar.Entry.create gram "scalar constant"
		
let rec multi_prod loc = function
  | [ x ] -> x
  | x :: l -> mk loc (Prod (x, multi_prod loc l))
  | [] -> assert false
      
let rec tuple loc = function
  | [ x ] -> x
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  | x :: l -> mk loc (Pair (x, tuple loc l))
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  | [] -> assert false
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let tuple_queue = 
  List.fold_right (fun x q -> mk x.loc (Pair (x, q)))

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let char = mk noloc (Internal (Types.char Chars.any))
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let string_regexp = Star (Elem char)
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let cst_nil =  mk noloc (Cst (Types.Atom Sequence.nil_atom))
		 
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let seq_of_string pos s =
  let (pos,_) = pos in
  let rec aux accu i = 
    if (i = 0) 
    then accu 
    else aux (((pos+i,pos+i+1),s.[i-1])::accu) (i-1) in
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  aux [] (String.length s)

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exception Error of string
let error loc s = raise (Location (loc, Error s))

let parse_char loc s =
  (* TODO: Unicode *)
  if String.length s <> 1 then
    error loc "Character litteral must have length 1";
  s.[0]
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let char_list pos s = 
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  let s = seq_of_string pos s in
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  List.map (fun (loc,c) -> mk loc (Cst (Types.Char (Chars.Unichar.from_char c)))) s
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EXTEND
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  GLOBAL: prog expr pat regexp const;

  prog: [
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    [ l = LIST0 [ p = phrase; ";;" -> mk loc p ]; EOI -> l ]
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  ];

  phrase: [
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    [ (p,e) = let_binding -> LetDecl (p,e)
    | (p,e1) = let_binding; "in"; e2 = expr LEVEL "top"->
        EvalStatement (mk loc (Match (e1,[p,e2])))
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    | LIDENT "type"; x = UIDENT; "="; t = pat -> TypeDecl (x,t)
    | LIDENT "debug"; d = debug_directive -> Debug d
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    ] | 
    [ e = expr -> EvalStatement e 
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    ]
  ];

  debug_directive: [
    [ LIDENT "filter"; t = pat; p = pat -> `Filter(t,p)
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    | LIDENT "accept"; p = pat -> `Accept p
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    | LIDENT "compile"; t = pat; p = LIST1 pat -> `Compile (t,p)
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    | LIDENT "normal_record"; t = pat -> `Normal_record t
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    ]
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  ];
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  expr: [
    "top" RIGHTA
    [ "match"; e = SELF; "with"; b = branches -> mk loc (Match (e,b))
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    | "try"; e = SELF; "with"; b = branches -> 
	let default = 
	  (mk noloc (Capture "x"),
	   mk noloc (Op ("raise",[mk noloc (Var "x")]))) in
	mk loc (Try (e,b@[default]))
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    | "map"; e = SELF; "with"; b = branches -> mk loc (Map (e,b))
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    | "transform"; e = SELF; "with"; b = branches -> 
	mk noloc (Op ("flatten", [mk loc (Map (e,b))]))
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    | "fun"; (f,a,b) = fun_decl ->
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	mk loc (Abstraction { fun_name = f; fun_iface = a; fun_body = b })
    | (p,e1) = let_binding; "in"; e2 = expr LEVEL "top"->
        mk loc (Match (e1,[p,e2]))
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    | e = expr; ":"; p = pat ->
	mk loc (Forget (e,p))
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    ]

    
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    | 
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    [ e1 = expr; op = ["+" | "-" | "@"]; e2 = expr -> mk loc (Op (op,[e1;e2]))
    ]
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    |
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    [ e1 = expr; op = ["*" | "/"]; e2 = expr -> mk loc (Op (op,[e1;e2]))  
    ]
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    |
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    [ e = expr;  "."; l = [LIDENT | UIDENT] -> 
	mk loc (Dot (e,Types.LabelPool.mk l)) 
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    ]  
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    |
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    [ op = [ LIDENT "flatten"
	   | LIDENT "load_xml"
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	   | LIDENT "print_xml"
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	   | LIDENT "raise" 
	   | LIDENT "int_of"
	   ]; 
      e = expr -> mk loc (Op (op,[e]))
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    | e1 = expr; e2 = expr -> mk loc (Apply (e1,e2))
    ]

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    | "no_appl" 
    [ c = const -> mk loc (Cst c)
    | "("; l = LIST1 expr SEP ","; ")" -> tuple loc l
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    | "[";  l = LIST0 seq_elem; e = OPT [ ";"; e = expr -> e ]; "]" ->
	let e = match e with Some e -> e | None -> cst_nil in
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	List.fold_right 
	  (fun x q ->
	     match x with
	       | `Elems l -> tuple_queue l q
	       | `Explode x -> mk x.loc (Op ("@",[x;q]))
	  ) l e
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    | t = [ a = TAG -> 
	      mk loc (Cst (Types.Atom (Types.AtomPool.mk a)))
	  | "<"; e = expr LEVEL "no_appl" -> e ];
	a = expr_attrib_spec; ">"; c = expr ->
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	mk loc (Xml (t, mk loc (Pair (a,c))))
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    | "{"; r = [ expr_record_spec | -> mk loc (RecordLitt []) ]; "}" -> r
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    | s = STRING2 ->
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	tuple loc (char_list loc s @ [cst_nil])
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    | a = LIDENT -> mk loc (Var a)
    ]

  ];
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  seq_elem: [
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    [ x = STRING1 -> `Elems (char_list loc x)
    | e = expr LEVEL "no_appl" -> `Elems [e]
    | "!"; e = expr LEVEL "no_appl" -> `Explode e
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    ]
  ];
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  let_binding: [
    [ "let"; p = pat; "="; e = expr -> (p,e)
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    | "let"; p = pat; ":"; t = pat; "="; e = expr -> (p, mk noloc (Forget (e,t)))
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    | "let"; "fun"; (f,a,b) = fun_decl ->
	let p = match f with 
	  | Some x -> mk loc (Capture x)
	  | _ -> failwith "Function name mandatory in let fun declarations"
	in
	let abst = { fun_name = f; fun_iface = a; fun_body = b } in
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        let e = mk loc (Abstraction abst) in
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        (p,e);
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    ] 
  ];

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 fun_decl: [
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(* need an hack to do this, because both productions would
   match   [ OPT LIDENT; "("; pat ] .... *)
   [ f = OPT LIDENT; "("; p1 = pat LEVEL "no_arrow";
    res = [ "->"; p2 = pat;
	    a = [ ";"; a = LIST0 arrow SEP ";" -> a | -> [] ];
	    ")"; b = branches -> `Classic (p2,a,b)
	  | ":"; targ1 = pat;
	    args = LIST0 [ ","; arg = pat; ":"; targ = pat -> (arg,targ) ]; 
	    ")"; ":"; tres = pat ; 
	    "="; body = expr ->
	      `Compact (targ1,args,tres,body)
	  ] ->
      match res with
	| `Classic (p2,a,b) -> f,(p1,p2)::a,b
	| `Compact (targ1,args,tres,body) ->
	    let args = (p1,targ1) :: args in
	    let targ = multi_prod noloc (List.map snd args) in
	    let arg = multi_prod noloc (List.map fst args) in
	    let b = [arg, body] in
	    let a = [targ,tres] in
	    (f,a,b)
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  ]
 ];

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 arrow: [
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    [ t1 = pat LEVEL "no_arrow"; "->"; t2 = pat -> (t1,t2)]
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  ];

  branches: [
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    [ OPT "|"; l = LIST1 branch SEP "|" -> l ]
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  ];

  branch: [
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    [ p = pat LEVEL "no_arrow"; "->"; e = expr -> (p,e) ]
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  ];

	  
  regexp: [ 
    [ x = regexp; "|"; y = regexp -> Alt (x,y) ]
  | [ x = regexp; y = regexp -> Seq (x,y) ]
  | [ a = LIDENT; "::"; x = regexp -> SeqCapture (a,x) ]
  | [ x = regexp; "*" -> Star x
    | x = regexp; "*?" -> WeakStar x
    | x = regexp; "+" -> Seq (x, Star x)
    | x = regexp; "+?" -> Seq (x, WeakStar x)
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    | x = regexp; "?" ->  Alt (x, Epsilon)
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    | x = regexp; "??" -> Alt (Epsilon, x) ]
  | [ "("; x = regexp; ")" -> x
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    | UIDENT "PCDATA" -> string_regexp
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    | i = STRING1; "--"; j = STRING1 ->
	let i = Chars.Unichar.from_char (parse_char loc i)
	and j = Chars.Unichar.from_char (parse_char loc j) in
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        Elem (mk loc (Internal (Types.char (Chars.char_class i j))))
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    |  s = STRING1 ->
	let s = seq_of_string loc s in
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	List.fold_right
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	  (fun (loc,c) accu -> 
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	     let c = Chars.Unichar.from_char c in
	     let c = Chars.atom c in
	     Seq (Elem (mk loc (Internal (Types.char c))), accu))
	  s
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	  Epsilon 
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    | e = pat LEVEL "simple" -> Elem e
    ]
  ];

  pat: [ 
      [ x = pat; "where"; 
        b = LIST1 [ a = UIDENT; "="; y = pat -> (a,y)] SEP "and"
            -> mk loc (Recurs (x,b)) ]
    | RIGHTA [ x = pat; "->"; y = pat -> mk loc (Arrow (x,y)) ]
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    | "no_arrow" [ x = pat; "|"; y = pat -> mk loc (Or (x,y)) ] 
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    | "simple" [ x = pat; "&"; y = pat -> mk loc (And (x,y,true)) 
(*	       | x = pat; ":"; y = pat -> mk loc (And (x,y,false))   *)
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	       | x = pat; "\\"; y = pat -> mk loc (Diff (x,y)) ]
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    | 
      [ "{"; r = record_spec; "}" -> r
      | LIDENT "_" -> mk loc (Internal Types.any)
      | a = LIDENT -> mk loc (Capture a)
      | "("; a = LIDENT; ":="; c = const; ")" -> mk loc (Constant (a,c))
      | a = UIDENT -> mk loc (PatVar a)
      | i = INT ; "--"; j = INT -> 
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          let i = Big_int.big_int_of_string i 
	  and j = Big_int.big_int_of_string j in
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          mk loc (Internal (Types.interval (Intervals.bounded i j)))
      | i = INT -> 
          let i = Big_int.big_int_of_string i  in
          mk loc (Internal (Types.interval (Intervals.atom i)))
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      | "*"; "--"; j = INT ->
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	  let j = Big_int.big_int_of_string j in
          mk loc (Internal (Types.interval (Intervals.left j)))
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      | i = INT; "--"; "*" ->
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	  let i = Big_int.big_int_of_string i in
          mk loc (Internal (Types.interval (Intervals.right i)))
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      | i = char ->
          mk loc (Internal (Types.char (Chars.char_class i i)))
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      | i = char ; "--"; j = char ->
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          mk loc (Internal (Types.char (Chars.char_class i j)))
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      | c = const -> mk loc (Internal (Types.constant c))
      | "("; l = LIST1 pat SEP ","; ")" -> multi_prod loc l
      | "["; r = [ r = regexp -> r | -> Epsilon ];
             q = [ ";"; q = pat -> q 
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                 | -> mk noloc (Internal (Sequence.nil_type)) ]; 
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             "]" -> mk loc (Regexp (r,q))
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      | t = [
	  [ "<"; LIDENT "_" -> mk loc (Internal (Types.atom (Atoms.any)))
	  | a = TAG -> 
	      mk loc 
	      (Internal (Types.atom (Atoms.atom (Types.AtomPool.mk a)))) ]
	| [ "<"; t = pat -> t ]
	];
	a = attrib_spec; ">"; c = pat ->
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          mk loc (XmlT (t, multi_prod loc [a;c]))
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      | s = STRING2 ->
	  let s = seq_of_string loc s in
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	  let s = List.map 
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		    (fun (loc,c) -> 
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		       mk loc (Internal
				 (Types.char
				    (Chars.atom
				       (Chars.Unichar.from_char c))))) s in
	  let s = s @ [mk loc (Internal (Sequence.nil_type))] in
	  multi_prod loc s
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      ]
    
  ];

  record_spec:
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    [ [ r = LIST0 [ l = [LIDENT | UIDENT]; "=";
                  o = [ "?" -> true | -> false]; 
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                  x = pat ->
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                    mk loc (Record (Types.LabelPool.mk l,o,x))
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                ] SEP ";" ->
        match r with
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          | [] -> mk loc (Internal Types.Record.any)
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          | h::t -> List.fold_left (fun t1 t2 -> mk loc (And (t1,t2,true))) h t
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      ] ];
  
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  char:
    [ 
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      [ c = STRING1 -> Chars.Unichar.from_char (parse_char loc c)
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      | "!"; i = INT -> Chars.Unichar.from_int (int_of_string i) ]
    ];
     

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  const:
    [ 
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      [ i = INT -> Types.Integer (Big_int.big_int_of_string i)
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      | "`"; a = [LIDENT | UIDENT] -> Types.Atom (Types.AtomPool.mk a)
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      | c = char -> Types.Char c ]
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    ];


  attrib_spec:
    [ [ r = record_spec -> r | "("; t = pat; ")" -> t ] ];

  expr_record_spec:
    [ [ r = LIST1
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	      [ l = [LIDENT | UIDENT]; "="; x = expr -> 
		  (Types.LabelPool.mk l,x) ] 
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	      SEP ";" ->
	  mk loc (RecordLitt r)
      ] ];
  
  expr_attrib_spec:
    [ [ r = expr_record_spec -> r ]
    | [ e = expr LEVEL "no_appl" -> e 
      | -> mk loc (RecordLitt []) 
      ] 
    ];
END

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let pat'  = Grammar.Entry.create gram "type/pattern expression"
EXTEND GLOBAL: pat pat';
  pat': [  [ p = pat; EOI -> p ] ];
END

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let pat = Grammar.Entry.parse pat
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and expr = Grammar.Entry.parse expr
and prog = Grammar.Entry.parse prog
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module From_string = struct
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  let pat s = Grammar.Entry.parse pat' (Stream.of_string s)
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  let expr s = expr (Stream.of_string s)
end
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