New content level representations for LetRec, Inductive and CoInductive.

[helm.git] / components / grafite_parser / grafiteParser.ml

(* Copyright (C) 2005, HELM Team.
 * 
 * This file is part of HELM, an Hypertextual, Electronic
 * Library of Mathematics, developed at the Computer Science
 * Department, University of Bologna, Italy.
 * 
 * HELM is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 * 
 * HELM is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with HELM; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place - Suite 330, Boston,
 * MA  02111-1307, USA.
 * 
 * For details, see the HELM World-Wide-Web page,
 * http://helm.cs.unibo.it/
 *)

(* $Id$ *)

open Printf

module Ast = CicNotationPt

type 'a localized_option =
   LSome of 'a
 | LNone of GrafiteAst.loc

type ast_statement =
  (CicNotationPt.term, CicNotationPt.term,
   CicNotationPt.term GrafiteAst.reduction, CicNotationPt.obj, string)
    GrafiteAst.statement

type statement =
  include_paths:string list ->
  LexiconEngine.status ->
    LexiconEngine.status * ast_statement localized_option

let grammar = CicNotationParser.level2_ast_grammar

let term = CicNotationParser.term
let statement = Grammar.Entry.create grammar "statement"

let add_raw_attribute ~text t = Ast.AttributedTerm (`Raw text, t)

let default_precedence = 50
let default_associativity = Gramext.NonA

type by_continuation =
   BYC_done
 | BYC_weproved of CicNotationPt.term * string option * CicNotationPt.term option
 | BYC_letsuchthat of string * CicNotationPt.term * string * CicNotationPt.term
 | BYC_wehaveand of string * CicNotationPt.term * string * CicNotationPt.term

EXTEND
  GLOBAL: term statement;
  constructor: [ [ name = IDENT; SYMBOL ":"; typ = term -> (name, typ) ] ];
  tactic_term: [ [ t = term LEVEL "90N" -> t ] ];
  ident_list0: [ [ LPAREN; idents = LIST0 IDENT; RPAREN -> idents ] ];
  tactic_term_list1: [
    [ tactic_terms = LIST1 tactic_term SEP SYMBOL "," -> tactic_terms ]
  ];
  reduction_kind: [
    [ IDENT "normalize" -> `Normalize
    | IDENT "reduce" -> `Reduce
    | IDENT "simplify" -> `Simpl
    | IDENT "unfold"; t = OPT tactic_term -> `Unfold t
    | IDENT "whd" -> `Whd ]
  ];
  sequent_pattern_spec: [
   [ hyp_paths =
      LIST0
       [ id = IDENT ;
         path = OPT [SYMBOL ":" ; path = tactic_term -> path ] ->
         (id,match path with Some p -> p | None -> Ast.UserInput) ];
     goal_path = OPT [ SYMBOL <:unicode<vdash>>; term = tactic_term -> term ] ->
      let goal_path =
       match goal_path, hyp_paths with
          None, [] -> Some Ast.UserInput
        | None, _::_ -> None
        | Some goal_path, _ -> Some goal_path
      in
       hyp_paths,goal_path
   ]
  ];
  pattern_spec: [
    [ res = OPT [
       "in";
       wanted_and_sps =
        [ "match" ; wanted = tactic_term ;
          sps = OPT [ "in"; sps = sequent_pattern_spec -> sps ] ->
           Some wanted,sps
        | sps = sequent_pattern_spec ->
           None,Some sps
        ] ->
         let wanted,hyp_paths,goal_path =
          match wanted_and_sps with
             wanted,None -> wanted, [], Some Ast.UserInput
           | wanted,Some (hyp_paths,goal_path) -> wanted,hyp_paths,goal_path
         in
          wanted, hyp_paths, goal_path ] ->
      match res with
         None -> None,[],Some Ast.UserInput
       | Some ps -> ps]
  ];
  direction: [
    [ SYMBOL ">" -> `LeftToRight
    | SYMBOL "<" -> `RightToLeft ]
  ];
  int: [ [ num = NUMBER -> int_of_string num ] ];
  intros_spec: [
    [ num = OPT [ num = int -> num ]; idents = OPT ident_list0 ->
        let idents = match idents with None -> [] | Some idents -> idents in
        num, idents
    ]
  ];
  using: [ [ using = OPT [ IDENT "using"; t = tactic_term -> t ] -> using ] ];
  tactic: [
    [ IDENT "absurd"; t = tactic_term ->
        GrafiteAst.Absurd (loc, t)
    | IDENT "apply"; t = tactic_term ->
        GrafiteAst.Apply (loc, t)
    | IDENT "applyS"; t = tactic_term ; params = 
        LIST0 [ i = IDENT -> i,"" | i = IDENT ; SYMBOL "="; v = [ v = int ->
          string_of_int v | v = IDENT -> v ] -> i,v ] ->
        GrafiteAst.ApplyS (loc, t, params)
    | IDENT "assumption" ->
        GrafiteAst.Assumption loc
    | IDENT "auto"; params = 
        LIST0 [ i = IDENT -> i,"" | i = IDENT ; SYMBOL "="; v = [ v = int ->
          string_of_int v | v = IDENT -> v ] -> i,v ] ->
        GrafiteAst.Auto (loc,params)
    | IDENT "clear"; ids = LIST1 IDENT ->
        GrafiteAst.Clear (loc, ids)
    | IDENT "clearbody"; id = IDENT ->
        GrafiteAst.ClearBody (loc,id)
    | IDENT "change"; what = pattern_spec; "with"; t = tactic_term ->
        GrafiteAst.Change (loc, what, t)
    | IDENT "constructor"; n = int ->
        GrafiteAst.Constructor (loc, n)
    | IDENT "contradiction" ->
        GrafiteAst.Contradiction loc
    | IDENT "cut"; t = tactic_term; ident = OPT [ "as"; id = IDENT -> id] ->
        GrafiteAst.Cut (loc, ident, t)
    | IDENT "decompose"; types = OPT ident_list0; what = OPT IDENT;
        idents = OPT [ "as"; idents = LIST1 IDENT -> idents ] ->
        let types = match types with None -> [] | Some types -> types in
        let idents = match idents with None -> [] | Some idents -> idents in
        let to_spec id = GrafiteAst.Ident id in
        GrafiteAst.Decompose (loc, List.rev_map to_spec types, what, idents)
    | IDENT "demodulate" -> GrafiteAst.Demodulate loc
    | IDENT "destruct"; t = tactic_term ->
        GrafiteAst.Destruct (loc, t)
    | IDENT "elim"; what = tactic_term; using = using;
      (num, idents) = intros_spec ->
        GrafiteAst.Elim (loc, what, using, num, idents)
    | IDENT "elimType"; what = tactic_term; using = using;
      (num, idents) = intros_spec ->
        GrafiteAst.ElimType (loc, what, using, num, idents)
    | IDENT "exact"; t = tactic_term ->
        GrafiteAst.Exact (loc, t)
    | IDENT "exists" ->
        GrafiteAst.Exists loc
    | IDENT "fail" -> GrafiteAst.Fail loc
    | IDENT "fold"; kind = reduction_kind; t = tactic_term; p = pattern_spec ->
        let (pt,_,_) = p in
          if pt <> None then
            raise (HExtlib.Localized (loc, CicNotationParser.Parse_error
              ("the pattern cannot specify the term to replace, only its"
              ^ " paths in the hypotheses and in the conclusion")))
        else
         GrafiteAst.Fold (loc, kind, t, p)
    | IDENT "fourier" ->
        GrafiteAst.Fourier loc
    | IDENT "fwd"; hyp = IDENT; idents = OPT [ "as"; idents = LIST1 IDENT -> idents ] ->
        let idents = match idents with None -> [] | Some idents -> idents in
        GrafiteAst.FwdSimpl (loc, hyp, idents)
    | IDENT "generalize"; p=pattern_spec; id = OPT ["as" ; id = IDENT -> id] ->
       GrafiteAst.Generalize (loc,p,id)
    | IDENT "goal"; n = int ->
        GrafiteAst.Goal (loc, n)
    | IDENT "id" -> GrafiteAst.IdTac loc
    | IDENT "intro"; ident = OPT IDENT ->
        let idents = match ident with None -> [] | Some id -> [id] in
        GrafiteAst.Intros (loc, Some 1, idents)
    | IDENT "intros"; (num, idents) = intros_spec ->
        GrafiteAst.Intros (loc, num, idents)
    | IDENT "inversion"; t = tactic_term ->
        GrafiteAst.Inversion (loc, t)
    | IDENT "lapply"; 
      linear = OPT [ IDENT "linear" ];
      depth = OPT [ IDENT "depth"; SYMBOL "="; i = int -> i ];
      what = tactic_term; 
      to_what = OPT [ "to" ; t = tactic_term_list1 -> t ];
      ident = OPT [ "as" ; ident = IDENT -> ident ] ->
        let linear = match linear with None -> false | Some _ -> true in 
        let to_what = match to_what with None -> [] | Some to_what -> to_what in
        GrafiteAst.LApply (loc, linear, depth, to_what, what, ident)
    | IDENT "left" -> GrafiteAst.Left loc
    | IDENT "letin"; where = IDENT ; SYMBOL <:unicode<def>> ; t = tactic_term ->
        GrafiteAst.LetIn (loc, t, where)
    | kind = reduction_kind; p = pattern_spec ->
        GrafiteAst.Reduce (loc, kind, p)
    | IDENT "reflexivity" ->
        GrafiteAst.Reflexivity loc
    | IDENT "replace"; p = pattern_spec; "with"; t = tactic_term ->
        GrafiteAst.Replace (loc, p, t)
    | IDENT "rewrite" ; d = direction; t = tactic_term ; p = pattern_spec ->
       let (pt,_,_) = p in
        if pt <> None then
         raise
          (HExtlib.Localized (loc,
           (CicNotationParser.Parse_error
            "the pattern cannot specify the term to rewrite, only its paths in the hypotheses and in the conclusion")))
        else
         GrafiteAst.Rewrite (loc, d, t, p)
    | IDENT "right" ->
        GrafiteAst.Right loc
    | IDENT "ring" ->
        GrafiteAst.Ring loc
    | IDENT "split" ->
        GrafiteAst.Split loc
    | IDENT "subst" ->
        GrafiteAst.Subst loc    
    | IDENT "symmetry" ->
        GrafiteAst.Symmetry loc
    | IDENT "transitivity"; t = tactic_term ->
        GrafiteAst.Transitivity (loc, t)
     (* Produzioni Aggiunte *)
    | IDENT "assume" ; id = IDENT ; SYMBOL ":" ; t = tactic_term ->
        GrafiteAst.Assume (loc, id, t)
    | IDENT "suppose" ; t = tactic_term ; LPAREN ; id = IDENT ; RPAREN ; t1 = OPT [IDENT "that" ; IDENT "is" ; IDENT "equivalent" ; "to" ; t' = tactic_term -> t']->
        GrafiteAst.Suppose (loc, t, id, t1)
    | IDENT "by" ; t = [t' = tactic_term -> LSome t' | SYMBOL "_" -> LNone loc];
      cont=by_continuation ->
       let t' = match t with LNone _ -> None | LSome t -> Some t in
       (match cont with
           BYC_done -> GrafiteAst.Bydone (loc, t')
         | BYC_weproved (ty,id,t1) ->
            GrafiteAst.By_term_we_proved(loc, t', ty, id, t1)
         | BYC_letsuchthat (id1,t1,id2,t2) ->
            (match t with
                LNone floc ->
                 raise (HExtlib.Localized
                  (floc,CicNotationParser.Parse_error
                    "tactic_term expected here"))
              | LSome t -> GrafiteAst.ExistsElim (loc, t, id1, t1, id2, t2))
         | BYC_wehaveand (id1,t1,id2,t2) ->
            (match t with
                LNone floc ->
                 raise (HExtlib.Localized
                  (floc,CicNotationParser.Parse_error
                    "tactic_term expected here"))
              | LSome t -> GrafiteAst.AndElim (loc, t, id1, t1, id2, t2)))
    | IDENT "we" ; IDENT "need" ; "to" ; IDENT "prove" ; t = tactic_term ; id = OPT [ LPAREN ; id = IDENT ; RPAREN -> id ] ; t1 = OPT [IDENT "or" ; IDENT "equivalently"; t' = tactic_term -> t']->
        GrafiteAst.We_need_to_prove (loc, t, id, t1)
    | IDENT "we" ; IDENT "proceed" ; IDENT "by" ; IDENT "induction" ; "on" ; t=tactic_term ; "to" ; IDENT "prove" ; t1=tactic_term ->  
        GrafiteAst.We_proceed_by_induction_on (loc, t, t1)
    | IDENT "by" ; IDENT "induction" ; IDENT "hypothesis" ; IDENT "we" ; IDENT "know" ; t=tactic_term ; LPAREN ; id = IDENT ; RPAREN ->
        GrafiteAst.Byinduction(loc, t, id)
    | IDENT "the" ; IDENT "thesis" ; IDENT "becomes" ; t=tactic_term ->
        GrafiteAst.Thesisbecomes(loc, t)
    | IDENT "case" ; id = IDENT ; params=LIST0[LPAREN ; i=IDENT ;
        SYMBOL":" ; t=tactic_term ; RPAREN -> i,t] ->
         GrafiteAst.Case(loc,id,params)
    | IDENT "obtain" ; termine=tactic_term ; SYMBOL "=" ; t1=tactic_term ; IDENT "by" ; t2=[ t=tactic_term -> Some t | SYMBOL "_" -> None  ] ; cont=rewriting_step_continuation ->
     GrafiteAst.RewritingStep(loc, Some termine, t1, t2, cont)
    | SYMBOL "=" ; t1=tactic_term ; IDENT "by" ; t2=[ t=tactic_term -> Some t | SYMBOL "_" -> None  ] ; cont=rewriting_step_continuation  ->
     GrafiteAst.RewritingStep(loc, None, t1, t2, cont)
  ]
];
  by_continuation: [
    [ IDENT "we" ; IDENT "proved" ; ty = tactic_term ; LPAREN ; id = IDENT ; RPAREN ; t1 = OPT [IDENT "that" ; IDENT "is" ; IDENT "equivalent" ; "to" ; t2 = tactic_term -> t2] -> BYC_weproved (ty,Some id,t1)
    | IDENT "we" ; IDENT "proved" ; ty = tactic_term ; t1 = OPT [IDENT "that" ; IDENT "is" ; IDENT "equivalent" ; "to" ; t2 = tactic_term -> t2] ; 
            IDENT "done" -> BYC_weproved (ty,None,t1)
    | IDENT "done" -> BYC_done
    | "let" ; id1 = IDENT ; SYMBOL ":" ; t1 = tactic_term ;
      IDENT "such" ; IDENT "that" ; t2=tactic_term ; LPAREN ; id2 = IDENT ; RPAREN -> BYC_letsuchthat (id1,t1,id2,t2)
    | IDENT "we" ; IDENT "have" ; t1=tactic_term ; LPAREN ; id1=IDENT ; RPAREN ;"and" ; t2=tactic_term ; LPAREN ; id2=IDENT ; RPAREN ->
              BYC_wehaveand (id1,t1,id2,t2)
    ]
];
  rewriting_step_continuation : [
    [ IDENT "done" -> None
    | IDENT "we" ; IDENT "proved" ; id=IDENT -> Some (Cic.Name id)
    | -> Some Cic.Anonymous
    ]
];
  atomic_tactical:
    [ "sequence" LEFTA
      [ t1 = SELF; SYMBOL ";"; t2 = SELF ->
          let ts =
            match t1 with
            | GrafiteAst.Seq (_, l) -> l @ [ t2 ]
            | _ -> [ t1; t2 ]
          in
          GrafiteAst.Seq (loc, ts)
      ]
    | "then" NONA
      [ tac = SELF; SYMBOL ";";
        SYMBOL "["; tacs = LIST0 SELF SEP SYMBOL "|"; SYMBOL "]"->
          (GrafiteAst.Then (loc, tac, tacs))
      ]
    | "loops" RIGHTA
      [ IDENT "do"; count = int; tac = SELF; IDENT "end" ->
          GrafiteAst.Do (loc, count, tac)
      | IDENT "repeat"; tac = SELF; IDENT "end" -> GrafiteAst.Repeat (loc, tac)
      ]
    | "simple" NONA
      [ IDENT "first";
        SYMBOL "["; tacs = LIST0 SELF SEP SYMBOL "|"; SYMBOL "]"->
          GrafiteAst.First (loc, tacs)
      | IDENT "try"; tac = SELF -> GrafiteAst.Try (loc, tac)
      | IDENT "solve";
        SYMBOL "["; tacs = LIST0 SELF SEP SYMBOL "|"; SYMBOL "]"->
          GrafiteAst.Solve (loc, tacs)
      | IDENT "progress"; tac = SELF -> GrafiteAst.Progress (loc, tac)
      | LPAREN; tac = SELF; RPAREN -> tac
      | tac = tactic -> GrafiteAst.Tactic (loc, tac)
      ]
    ];
  punctuation_tactical:
    [
      [ SYMBOL "[" -> GrafiteAst.Branch loc
      | SYMBOL "|" -> GrafiteAst.Shift loc
      | i = LIST1 int SEP SYMBOL ","; SYMBOL ":" -> GrafiteAst.Pos (loc, i)
      | SYMBOL "*"; SYMBOL ":" -> GrafiteAst.Wildcard loc
      | SYMBOL "]" -> GrafiteAst.Merge loc
      | SYMBOL ";" -> GrafiteAst.Semicolon loc
      | SYMBOL "." -> GrafiteAst.Dot loc
      ]
    ];
  tactical:
    [ "simple" NONA
      [ IDENT "focus"; goals = LIST1 int -> GrafiteAst.Focus (loc, goals)
      | IDENT "unfocus" -> GrafiteAst.Unfocus loc
      | IDENT "skip" -> GrafiteAst.Skip loc
      | tac = atomic_tactical LEVEL "loops" -> tac
      ]
    ];
  theorem_flavour: [
    [ [ IDENT "definition"  ] -> `Definition
    | [ IDENT "fact"        ] -> `Fact
    | [ IDENT "lemma"       ] -> `Lemma
    | [ IDENT "remark"      ] -> `Remark
    | [ IDENT "theorem"     ] -> `Theorem
    ]
  ];
  inductive_spec: [ [
    fst_name = IDENT; params = LIST0 CicNotationParser.protected_binder_vars;
    SYMBOL ":"; fst_typ = term; SYMBOL <:unicode<def>>; OPT SYMBOL "|";
    fst_constructors = LIST0 constructor SEP SYMBOL "|";
    tl = OPT [ "with";
      types = LIST1 [
        name = IDENT; SYMBOL ":"; typ = term; SYMBOL <:unicode<def>>;
       OPT SYMBOL "|"; constructors = LIST0 constructor SEP SYMBOL "|" ->
          (name, true, typ, constructors) ] SEP "with" -> types
    ] ->
      let params =
        List.fold_right
          (fun (names, typ) acc ->
            (List.map (fun name -> (name, typ)) names) @ acc)
          params []
      in
      let fst_ind_type = (fst_name, true, fst_typ, fst_constructors) in
      let tl_ind_types = match tl with None -> [] | Some types -> types in
      let ind_types = fst_ind_type :: tl_ind_types in
      (params, ind_types)
  ] ];
  
  record_spec: [ [
    name = IDENT; params = LIST0 CicNotationParser.protected_binder_vars ;
     SYMBOL ":"; typ = term; SYMBOL <:unicode<def>>; SYMBOL "{" ; 
     fields = LIST0 [ 
       name = IDENT ; 
       coercion = [ 
           SYMBOL ":" -> false,0 
         | SYMBOL ":"; SYMBOL ">" -> true,0
         | SYMBOL ":"; arity = int ; SYMBOL ">" -> true,arity
       ]; 
       ty = term -> 
         let b,n = coercion in 
         (name,ty,b,n) 
     ] SEP SYMBOL ";"; SYMBOL "}" -> 
      let params =
        List.fold_right
          (fun (names, typ) acc ->
            (List.map (fun name -> (name, typ)) names) @ acc)
          params []
      in
      (params,name,typ,fields)
  ] ];
  
  macro: [
    [ [ IDENT "check"   ]; t = term ->
        GrafiteAst.Check (loc, t)
    | [ IDENT "inline"]; suri = QSTRING ->
         GrafiteAst.Inline (loc,suri)
    | [ IDENT "hint" ] -> GrafiteAst.Hint loc
    | [ IDENT "whelp"; "match" ] ; t = term -> 
        GrafiteAst.WMatch (loc,t)
    | [ IDENT "whelp"; IDENT "instance" ] ; t = term -> 
        GrafiteAst.WInstance (loc,t)
    | [ IDENT "whelp"; IDENT "locate" ] ; id = QSTRING -> 
        GrafiteAst.WLocate (loc,id)
    | [ IDENT "whelp"; IDENT "elim" ] ; t = term ->
        GrafiteAst.WElim (loc, t)
    | [ IDENT "whelp"; IDENT "hint" ] ; t = term -> 
        GrafiteAst.WHint (loc,t)
    ]
  ];
  alias_spec: [
    [ IDENT "id"; id = QSTRING; SYMBOL "="; uri = QSTRING ->
      let alpha = "[a-zA-Z]" in
      let num = "[0-9]+" in
      let ident_cont = "\\("^alpha^"\\|"^num^"\\|_\\|\\\\\\)" in
      let ident = "\\("^alpha^ident_cont^"*\\|_"^ident_cont^"+\\)" in
      let rex = Str.regexp ("^"^ident^"$") in
      if Str.string_match rex id 0 then
        if (try ignore (UriManager.uri_of_string uri); true
            with UriManager.IllFormedUri _ -> false)
        then
          LexiconAst.Ident_alias (id, uri)
        else 
          raise
           (HExtlib.Localized (loc, CicNotationParser.Parse_error (sprintf "Not a valid uri: %s" uri)))
      else
        raise (HExtlib.Localized (loc, CicNotationParser.Parse_error (
          sprintf "Not a valid identifier: %s" id)))
    | IDENT "symbol"; symbol = QSTRING;
      instance = OPT [ LPAREN; IDENT "instance"; n = int; RPAREN -> n ];
      SYMBOL "="; dsc = QSTRING ->
        let instance =
          match instance with Some i -> i | None -> 0
        in
        LexiconAst.Symbol_alias (symbol, instance, dsc)
    | IDENT "num";
      instance = OPT [ LPAREN; IDENT "instance"; n = int; RPAREN -> n ];
      SYMBOL "="; dsc = QSTRING ->
        let instance =
          match instance with Some i -> i | None -> 0
        in
        LexiconAst.Number_alias (instance, dsc)
    ]
  ];
  argument: [
    [ l = LIST0 [ SYMBOL <:unicode<eta>> (* η *); SYMBOL "." -> () ];
      id = IDENT ->
        Ast.IdentArg (List.length l, id)
    ]
  ];
  associativity: [
    [ IDENT "left";  IDENT "associative" -> Gramext.LeftA
    | IDENT "right"; IDENT "associative" -> Gramext.RightA
    | IDENT "non"; IDENT "associative" -> Gramext.NonA
    ]
  ];
  precedence: [
    [ "with"; IDENT "precedence"; n = NUMBER -> int_of_string n ]
  ];
  notation: [
    [ dir = OPT direction; s = QSTRING;
      assoc = OPT associativity; prec = OPT precedence;
      IDENT "for";
      p2 = 
        [ blob = UNPARSED_AST ->
            add_raw_attribute ~text:(sprintf "@{%s}" blob)
              (CicNotationParser.parse_level2_ast
                (Ulexing.from_utf8_string blob))
        | blob = UNPARSED_META ->
            add_raw_attribute ~text:(sprintf "${%s}" blob)
              (CicNotationParser.parse_level2_meta
                (Ulexing.from_utf8_string blob))
        ] ->
          let assoc =
            match assoc with
            | None -> default_associativity
            | Some assoc -> assoc
          in
          let prec =
            match prec with
            | None -> default_precedence
            | Some prec -> prec
          in
          let p1 =
            add_raw_attribute ~text:s
              (CicNotationParser.parse_level1_pattern
                (Ulexing.from_utf8_string s))
          in
          (dir, p1, assoc, prec, p2)
    ]
  ];
  level3_term: [
    [ u = URI -> Ast.UriPattern (UriManager.uri_of_string u)
    | id = IDENT -> Ast.VarPattern id
    | SYMBOL "_" -> Ast.ImplicitPattern
    | LPAREN; terms = LIST1 SELF; RPAREN ->
        (match terms with
        | [] -> assert false
        | [term] -> term
        | terms -> Ast.ApplPattern terms)
    ]
  ];
  interpretation: [
    [ s = CSYMBOL; args = LIST0 argument; SYMBOL "="; t = level3_term ->
        (s, args, t)
    ]
  ];
  
  include_command: [ [
      IDENT "include" ; path = QSTRING -> 
        loc,path,LexiconAst.WithPreferences
    | IDENT "include'" ; path = QSTRING -> 
        loc,path,LexiconAst.WithoutPreferences
   ]];

  grafite_command: [ [
      IDENT "set"; n = QSTRING; v = QSTRING ->
        GrafiteAst.Set (loc, n, v)
    | IDENT "drop" -> GrafiteAst.Drop loc
    | IDENT "print"; s = IDENT -> GrafiteAst.Print (loc,s)
    | IDENT "qed" -> GrafiteAst.Qed loc
    | IDENT "variant" ; name = IDENT; SYMBOL ":"; 
      typ = term; SYMBOL <:unicode<def>> ; newname = IDENT ->
        GrafiteAst.Obj (loc, 
          Ast.Theorem 
            (`Variant,name,typ,Some (Ast.Ident (newname, None))))
    | flavour = theorem_flavour; name = IDENT; SYMBOL ":"; typ = term;
      body = OPT [ SYMBOL <:unicode<def>> (* ≝ *); body = term -> body ] ->
        GrafiteAst.Obj (loc, Ast.Theorem (flavour, name, typ, body))
    | flavour = theorem_flavour; name = IDENT; SYMBOL <:unicode<def>> (* ≝ *);
      body = term ->
        GrafiteAst.Obj (loc,
          Ast.Theorem (flavour, name, Ast.Implicit, Some body))
    | IDENT "axiom"; name = IDENT; SYMBOL ":"; typ = term ->
        GrafiteAst.Obj (loc, Ast.Theorem (`Axiom, name, typ, None))
    | "let"; ind_kind = [ "corec" -> `CoInductive | "rec"-> `Inductive ];
        defs = CicNotationParser.let_defs -> 
          let name,ty = 
            match defs with
            | (params,(Ast.Ident (name, None), Some ty),_,_) :: _ ->
                let ty =
                 List.fold_right
                  (fun var ty -> Ast.Binder (`Pi,var,ty)
                  ) params ty
                in
                 name,ty
            | (_,(Ast.Ident (name, None), None),_,_) :: _ ->
                name, Ast.Implicit
            | _ -> assert false 
          in
          let body = Ast.Ident (name,None) in
          GrafiteAst.Obj (loc, Ast.Theorem(`Definition, name, ty,
            Some (Ast.LetRec (ind_kind, defs, body))))
    | IDENT "inductive"; spec = inductive_spec ->
        let (params, ind_types) = spec in
        GrafiteAst.Obj (loc, Ast.Inductive (params, ind_types))
    | IDENT "coinductive"; spec = inductive_spec ->
        let (params, ind_types) = spec in
        let ind_types = (* set inductive flags to false (coinductive) *)
          List.map (fun (name, _, term, ctors) -> (name, false, term, ctors))
            ind_types
        in
        GrafiteAst.Obj (loc, Ast.Inductive (params, ind_types))
    | IDENT "coercion" ; suri = URI ; arity = OPT int ->
        let arity = match arity with None -> 0 | Some x -> x in
        GrafiteAst.Coercion (loc, UriManager.uri_of_string suri, true, arity)
    | IDENT "record" ; (params,name,ty,fields) = record_spec ->
        GrafiteAst.Obj (loc, Ast.Record (params,name,ty,fields))
    | IDENT "default" ; what = QSTRING ; uris = LIST1 URI ->
       let uris = List.map UriManager.uri_of_string uris in
        GrafiteAst.Default (loc,what,uris)
    | IDENT "relation" ; aeq = tactic_term ; "on" ; a = tactic_term ;
      refl = OPT [ IDENT "reflexivity" ; IDENT "proved" ; IDENT "by" ;
                   refl = tactic_term -> refl ] ;
      sym = OPT [ IDENT "symmetry" ; IDENT "proved" ; IDENT "by" ;
                   sym = tactic_term -> sym ] ;
      trans = OPT [ IDENT "transitivity" ; IDENT "proved" ; IDENT "by" ;
                   trans = tactic_term -> trans ] ;
      "as" ; id = IDENT ->
       GrafiteAst.Relation (loc,id,a,aeq,refl,sym,trans)
  ]];
  lexicon_command: [ [
      IDENT "alias" ; spec = alias_spec ->
        LexiconAst.Alias (loc, spec)
    | IDENT "notation"; (dir, l1, assoc, prec, l2) = notation ->
        LexiconAst.Notation (loc, dir, l1, assoc, prec, l2)
    | IDENT "interpretation"; id = QSTRING;
      (symbol, args, l3) = interpretation ->
        LexiconAst.Interpretation (loc, id, (symbol, args), l3)
  ]];
  executable: [
    [ cmd = grafite_command; SYMBOL "." -> GrafiteAst.Command (loc, cmd)
    | tac = tactical; punct = punctuation_tactical ->
        GrafiteAst.Tactical (loc, tac, Some punct)
    | punct = punctuation_tactical -> GrafiteAst.Tactical (loc, punct, None)
    | mac = macro; SYMBOL "." -> GrafiteAst.Macro (loc, mac)
    ]
  ];
  comment: [
    [ BEGINCOMMENT ; ex = executable ; ENDCOMMENT -> 
       GrafiteAst.Code (loc, ex)
    | str = NOTE -> 
       GrafiteAst.Note (loc, str)
    ]
  ];
  statement: [
    [ ex = executable ->
       fun ~include_paths status -> status,LSome(GrafiteAst.Executable (loc,ex))
    | com = comment ->
       fun ~include_paths status -> status,LSome (GrafiteAst.Comment (loc, com))
    | (iloc,fname,mode) = include_command ; SYMBOL "."  ->
       fun ~include_paths status ->
        let buri, fullpath = 
          DependenciesParser.baseuri_of_script ~include_paths fname 
        in
        let status =
         LexiconEngine.eval_command status 
           (LexiconAst.Include (iloc,buri,mode,fullpath))
        in
         status,
          LSome
          (GrafiteAst.Executable
           (loc,GrafiteAst.Command
            (loc,GrafiteAst.Include (iloc,buri))))
    | scom = lexicon_command ; SYMBOL "." ->
       fun ~include_paths status ->
        let status = LexiconEngine.eval_command status scom in
         status,LNone loc
    | EOI -> raise End_of_file
    ]
  ];
END

let exc_located_wrapper f =
  try
    f ()
  with
  | Stdpp.Exc_located (_, End_of_file) -> raise End_of_file
  | Stdpp.Exc_located (floc, Stream.Error msg) ->
      raise (HExtlib.Localized (floc,CicNotationParser.Parse_error msg))
  | Stdpp.Exc_located (floc, exn) ->
      raise
       (HExtlib.Localized (floc,CicNotationParser.Parse_error (Printexc.to_string exn)))

let parse_statement lexbuf =
  exc_located_wrapper
    (fun () -> (Grammar.Entry.parse statement (Obj.magic lexbuf)))