* http://helm.cs.unibo.it/
*)
-let debug = true
+let debug = false
let debug_print s =
if debug then begin
prerr_endline "<NEW_TEXTUAL_PARSER>";
prerr_endline "</NEW_TEXTUAL_PARSER>"
end
+ (** if set to true each number will have a different insance number and can
+ * thus be interpreted differently than others *)
+let use_fresh_num_instances = false
+
+ (** does the lexer return COMMENT tokens? *)
+let return_comments = false
+
open Printf
-exception Parse_error of string
+open DisambiguateTypes
+
+exception Parse_error of Token.flocation * string
-let choice_of_uri (uri: string) =
- let cic = HelmLibraryObjects.term_of_uri (UriManager.uri_of_string uri) in
- (uri, (fun _ _ _ -> cic))
+let cic_lexer = CicTextualLexer2.cic_lexer ~comments:return_comments ()
-let grammar = Grammar.gcreate CicTextualLexer2.cic_lexer
+let fresh_num_instance =
+ let n = ref 0 in
+ if use_fresh_num_instances then
+ (fun () -> incr n; !n)
+ else
+ (fun () -> 0)
+
+let choice_of_uri uri =
+ let term = CicUtil.term_of_uri uri in
+ (uri, (fun _ _ _ -> term))
+
+let grammar = Grammar.gcreate cic_lexer
let term = Grammar.Entry.create grammar "term"
let term0 = Grammar.Entry.create grammar "term0"
-(* let tactic = Grammar.Entry.create grammar "tactic" *)
-(* let tactical = Grammar.Entry.create grammar "tactical" *)
+let tactic = Grammar.Entry.create grammar "tactic"
+let tactical = Grammar.Entry.create grammar "tactical"
+let tactical0 = Grammar.Entry.create grammar "tactical0"
+let command = Grammar.Entry.create grammar "command"
+let script = Grammar.Entry.create grammar "script"
let return_term loc term = CicAst.AttributedTerm (`Loc loc, term)
-(* let return_term loc term = term *)
+let return_tactic loc tactic = TacticAst.LocatedTactic (loc, tactic)
+let return_tactical loc tactical = TacticAst.LocatedTactical (loc, tactical)
+let return_command loc cmd = cmd (* TODO ZACK FIXME uhm ... why we drop loc? *)
-let fail (x, y) msg =
+let fail floc msg =
+ let (x, y) = CicAst.loc_of_floc floc in
failwith (Printf.sprintf "Error at characters %d - %d: %s" x y msg)
let name_of_string = function
| "_" -> Cic.Anonymous
| s -> Cic.Name s
+let string_of_name = function
+ | Cic.Anonymous -> "_"
+ | Cic.Name s -> s
+
+let int_opt = function
+ | None -> None
+ | Some lexeme -> Some (int_of_string lexeme)
+
+ (** the uri of an inductive type (a ".ind" uri) is not meaningful without an
+ * xpointer. Still, it's likely that an user who wrote "cic:/blabla/foo.ind"
+ * actually meant "cic:/blabla/foo.ind#xpointer(1/1)", i.e. the first inductive
+ * type in a block of mutual inductive types.
+ *
+ * This function performs the expansion foo.ind -> foo#xpointer..., if needed
+ *)
+let ind_expansion uri =
+ let len = String.length uri in
+ if len >= 4 && String.sub uri (len - 4) 4 = ".ind" then
+ uri ^ "#xpointer(1/1)"
+ else
+ uri
+
EXTEND
- GLOBAL: term term0;
+ GLOBAL: term term0 tactic tactical tactical0 command script;
+ int: [
+ [ num = NUM ->
+ try
+ int_of_string num
+ with Failure _ -> raise (Parse_error (loc, "integer literal expected"))
+ ]
+ ];
meta_subst: [
[ s = SYMBOL "_" -> None
| t = term -> Some t ]
];
binder: [
[ SYMBOL <:unicode<lambda>> (* λ *) -> `Lambda
- | SYMBOL <:unicode<pi>> (* π *) -> `Pi
+ | SYMBOL <:unicode<Pi>> (* Π *) -> `Pi
| SYMBOL <:unicode<exists>> (* ∃ *) -> `Exists
- | SYMBOL <:unicode<forall>> (* ∀ *) -> `Forall
- ]
+ | SYMBOL <:unicode<forall>> (* ∀ *) -> `Forall ]
+ ];
+ sort: [
+ [ "Prop" -> `Prop
+ | "Set" -> `Set
+ | "Type" -> `Type
+ | "CProp" -> `CProp ]
];
typed_name: [
[ PAREN "("; i = IDENT; SYMBOL ":"; typ = term; PAREN ")" ->
- (name_of_string i, Some typ)
- | i = IDENT -> (name_of_string i, None)
+ (Cic.Name i, Some typ)
+ | i = IDENT -> (Cic.Name i, None)
]
];
- substituted_name: [ (* a subs.name is an explicit substitution subject *)
- [ s = [ IDENT | SYMBOL ];
- subst = OPT [
- SYMBOL "\subst"; (* to avoid catching frequent "a [1]" cases *)
+ subst: [
+ [ subst = OPT [
+ SYMBOL "\\subst"; (* to avoid catching frequent "a [1]" cases *)
PAREN "[";
substs = LIST1 [
i = IDENT; SYMBOL <:unicode<Assign>> (* ≔ *); t = term -> (i, t)
] SEP SYMBOL ";";
PAREN "]" ->
substs
- ] ->
- (match subst with
- | Some l -> CicAst.Ident (s, l)
- | None -> CicAst.Ident (s, []))
+ ] -> subst
+ ]
+ ];
+ substituted_name: [ (* a subs.name is an explicit substitution subject *)
+ [ s = IDENT; subst = subst -> CicAst.Ident (s, subst)
+ | s = URI; subst = subst -> CicAst.Uri (ind_expansion s, subst)
]
];
name: [ (* as substituted_name with no explicit substitution *)
(head, vars)
]
];
- term0: [ [ t = term -> return_term loc t ] ];
+ let_defs:[
+ [ defs = LIST1 [
+ name = IDENT;
+ args = LIST1 [
+ PAREN "(" ; names = LIST1 IDENT SEP SYMBOL ","; SYMBOL ":";
+ ty = term; PAREN ")" ->
+ (names, ty)
+ ];
+ index_name = OPT [ IDENT "on"; idx = IDENT -> idx ];
+ ty = OPT [ SYMBOL ":" ; t = term -> t ];
+ SYMBOL <:unicode<def>> (* ≝ *);
+ t1 = term ->
+ let rec list_of_binder binder ty final_term = function
+ | [] -> final_term
+ | name::tl ->
+ CicAst.Binder (binder, (Cic.Name name, Some ty),
+ list_of_binder binder ty final_term tl)
+ in
+ let rec binder_of_arg_list binder final_term = function
+ | [] -> final_term
+ | (l,ty)::tl ->
+ list_of_binder binder ty
+ (binder_of_arg_list binder final_term tl) l
+ in
+ let t1' = binder_of_arg_list `Lambda t1 args in
+ let ty' =
+ match ty with
+ | None -> None
+ | Some ty -> Some (binder_of_arg_list `Pi ty args)
+ in
+ let rec get_position_of name n = function
+ | [] -> (None,n)
+ | nam::tl ->
+ if nam = name then
+ (Some n,n)
+ else
+ (get_position_of name (n+1) tl)
+ in
+ let rec find_arg name n = function
+ | [] -> (fail loc (sprintf "Argument %s not found" name))
+ | (l,_)::tl ->
+ let (got,len) = get_position_of name 0 l in
+ (match got with
+ | None -> (find_arg name (n+len) tl)
+ | Some where -> n + where)
+ in
+ let index =
+ (match index_name with
+ | None -> 0
+ | (Some name) -> find_arg name 0 args)
+ in
+ ((Cic.Name name,ty'), t1', index)
+ ] SEP "and" -> defs
+ ]];
+ constructor: [ [ name = IDENT; SYMBOL ":"; typ = term -> (name, typ) ] ];
+ term0: [ [ t = term; EOI -> return_term loc t ] ];
term:
- [ "arrow" RIGHTA
- [ t1 = term; SYMBOL <:unicode<to>>; t2 = term ->
- return_term loc
- (CicAst.Binder (`Pi, (Cic.Anonymous, Some t1), t2))
+ [ "letin" NONA
+ [ "let"; var = typed_name;
+ SYMBOL <:unicode<def>> (* ≝ *);
+ t1 = term; "in"; t2 = term ->
+ return_term loc (CicAst.LetIn (var, t1, t2))
+ | "let"; ind_kind = [ "corec" -> `CoInductive | "rec"-> `Inductive ];
+ defs = let_defs; "in"; body = term ->
+ return_term loc (CicAst.LetRec (ind_kind, defs, body))
]
| "binder" RIGHTA
[
- b = binder; vars = LIST1 IDENT SEP SYMBOL ",";
- typ = OPT [ SYMBOL ":"; t = term -> t ];
+ b = binder;
+ (vars, typ) =
+ [ vars = LIST1 IDENT SEP SYMBOL ",";
+ typ = OPT [ SYMBOL ":"; t = term -> t ] -> (vars, typ)
+ | PAREN "("; vars = LIST1 IDENT SEP SYMBOL ",";
+ typ = OPT [ SYMBOL ":"; t = term -> t ]; PAREN ")" -> (vars, typ)
+ ];
SYMBOL "."; body = term ->
let binder =
List.fold_right
vars body
in
return_term loc binder
+ | t1 = term; SYMBOL <:unicode<to>> (* → *); t2 = term ->
+ return_term loc
+ (CicAst.Binder (`Pi, (Cic.Anonymous, Some t1), t2))
]
- | "eq" LEFTA
+ | "logic_add" LEFTA [ (* nothing here by default *) ]
+ | "logic_mult" LEFTA [ (* nothing here by default *) ]
+ | "logic_inv" NONA [ (* nothing here by default *) ]
+ | "relop" LEFTA
[ t1 = term; SYMBOL "="; t2 = term ->
return_term loc (CicAst.Appl [CicAst.Symbol ("eq", 0); t1; t2])
]
| "add" LEFTA [ (* nothing here by default *) ]
| "mult" LEFTA [ (* nothing here by default *) ]
+ | "power" LEFTA [ (* nothing here by default *) ]
| "inv" NONA [ (* nothing here by default *) ]
+ | "apply" LEFTA
+ [ t1 = term; t2 = term ->
+ let rec aux = function
+ | CicAst.Appl (hd :: tl) -> aux hd @ tl
+ | term -> [term]
+ in
+ CicAst.Appl (aux t1 @ [t2])
+ ]
| "simple" NONA
- [
- sort_kind = [
- "Prop" -> `Prop | "Set" -> `Set | "Type" -> `Type | "CProp" -> `CProp
- ] ->
- CicAst.Sort sort_kind
+ [ sort = sort -> CicAst.Sort sort
| n = substituted_name -> return_term loc n
- | PAREN "("; head = term; args = LIST1 term; PAREN ")" ->
- return_term loc (CicAst.Appl (head :: args))
- | i = NUM -> return_term loc (CicAst.Num (i, 0))
+ | i = NUM -> return_term loc (CicAst.Num (i, (fresh_num_instance ())))
| IMPLICIT -> return_term loc CicAst.Implicit
| m = META;
substs = [
fail loc ("Invalid meta variable number: " ^ m)
in
return_term loc (CicAst.Meta (index, substs))
- (* actually "in" and "and" are _not_ keywords. Parsing works anyway
- * since applications are required to be bound by parens *)
- | "let"; var = typed_name;
-(* SYMBOL <:unicode<def>> (* ≝ *); *)
- SYMBOL "=";
- t1 = term;
- IDENT "in"; t2 = term ->
- return_term loc (CicAst.LetIn (var, t1, t2))
- | "let"; ind_kind = [ "corec" -> `CoInductive | "rec"-> `Inductive ];
- defs = LIST1 [
- var = typed_name;
- index = OPT [ PAREN "("; index = NUM; PAREN ")" ->
- int_of_string index
- ];
-(* SYMBOL <:unicode<def>> (* ≝ *); *)
- SYMBOL "=";
- t1 = term ->
- (var, t1, (match index with None -> 0 | Some i -> i))
- ] SEP (IDENT "and");
- IDENT "in"; body = term ->
- return_term loc (CicAst.LetRec (ind_kind, defs, body))
| outtyp = OPT [ PAREN "["; typ = term; PAREN "]" -> typ ];
"match"; t = term;
- SYMBOL ":"; indty = IDENT;
+ indty_ident = OPT [ SYMBOL ":"; id = IDENT -> id ];
"with";
PAREN "[";
patterns = LIST0 [
- lhs = pattern; SYMBOL <:unicode<Rightarrow>> (* ⇒ *); rhs = term ->
+ lhs = pattern; SYMBOL <:unicode<Rightarrow>> (* ⇒ *); rhs = term
+ ->
((lhs: CicAst.case_pattern), rhs)
] SEP SYMBOL "|";
PAREN "]" ->
return_term loc
- (CicAst.Case (t, indty, outtyp, patterns))
+ (CicAst.Case (t, indty_ident, outtyp, patterns))
+ | PAREN "("; t1 = term; SYMBOL ":"; t2 = term; PAREN ")" ->
+ return_term loc (CicAst.Appl [CicAst.Symbol ("cast", 0); t1; t2])
| PAREN "("; t = term; PAREN ")" -> return_term loc t
]
];
+ tactic_where: [
+ [ where = OPT [ "in"; ident = IDENT -> ident ] -> where ]
+ ];
+ tactic_term: [ [ t = term -> t ] ];
+ ident_list0: [
+ [ PAREN "["; idents = LIST0 IDENT SEP SYMBOL ";"; PAREN "]" -> idents ]
+ ];
+ ident_list1: [
+ [ PAREN "["; idents = LIST1 IDENT SEP SYMBOL ";"; PAREN "]" -> idents ]
+ ];
+ reduction_kind: [
+ [ [ IDENT "reduce" | IDENT "Reduce" ] -> `Reduce
+ | [ IDENT "simplify" | IDENT "Simplify" ] -> `Simpl
+ | [ IDENT "whd" | IDENT "Whd" ] -> `Whd ]
+ ];
+ tactic: [
+ [ [ IDENT "absurd" | IDENT "Absurd" ]; t = tactic_term ->
+ return_tactic loc (TacticAst.Absurd t)
+ | [ IDENT "apply" | IDENT "Apply" ]; t = tactic_term ->
+ return_tactic loc (TacticAst.Apply t)
+ | [ IDENT "assumption" | IDENT "Assumption" ] ->
+ return_tactic loc TacticAst.Assumption
+ | [ IDENT "auto" | IDENT "Auto" ] -> return_tactic loc TacticAst.Auto
+ | [ IDENT "change" | IDENT "Change" ];
+ t1 = tactic_term; "with"; t2 = tactic_term;
+ where = tactic_where ->
+ return_tactic loc (TacticAst.Change (t1, t2, where))
+ (* TODO Change_pattern *)
+ | [ IDENT "contradiction" | IDENT "Contradiction" ] ->
+ return_tactic loc TacticAst.Contradiction
+ | [ IDENT "cut" | IDENT "Cut" ];
+ t = tactic_term -> return_tactic loc (TacticAst.Cut t)
+ | [ IDENT "decompose" | IDENT "Decompose" ];
+ principles = ident_list1; where = IDENT ->
+ return_tactic loc (TacticAst.Decompose (where, principles))
+ | [ IDENT "discriminate" | IDENT "Discriminate" ];
+ hyp = IDENT ->
+ return_tactic loc (TacticAst.Discriminate hyp)
+ | [ IDENT "elimType" | IDENT "ElimType" ]; t = tactic_term ->
+ return_tactic loc (TacticAst.ElimType t)
+ | [ IDENT "elim" | IDENT "Elim" ];
+ t1 = tactic_term;
+ using = OPT [ "using"; using = tactic_term -> using ] ->
+ return_tactic loc (TacticAst.Elim (t1, using))
+ | [ IDENT "exact" | IDENT "Exact" ]; t = tactic_term ->
+ return_tactic loc (TacticAst.Exact t)
+ | [ IDENT "exists" | IDENT "Exists" ] ->
+ return_tactic loc TacticAst.Exists
+ | [ IDENT "fold" | IDENT "Fold" ];
+ kind = reduction_kind; t = tactic_term ->
+ return_tactic loc (TacticAst.Fold (kind, t))
+ | [ IDENT "fourier" | IDENT "Fourier" ] ->
+ return_tactic loc TacticAst.Fourier
+ | [ IDENT "hint" | IDENT "Hint" ] -> return_tactic loc TacticAst.Hint
+ | [ IDENT "injection" | IDENT "Injection" ]; ident = IDENT ->
+ return_tactic loc (TacticAst.Injection ident)
+ | [ IDENT "intros" | IDENT "Intros" ];
+ num = OPT [ num = int -> num ];
+ idents = OPT ident_list0 ->
+ let idents = match idents with None -> [] | Some idents -> idents in
+ return_tactic loc (TacticAst.Intros (num, idents))
+ | [ IDENT "intro" | IDENT "Intro" ] ->
+ return_tactic loc (TacticAst.Intros (None, []))
+ | [ IDENT "left" | IDENT "Left" ] -> return_tactic loc TacticAst.Left
+ | [ "let" | "Let" ];
+ t = tactic_term; "in"; where = IDENT ->
+ return_tactic loc (TacticAst.LetIn (t, where))
+ | kind = reduction_kind;
+ pat = OPT [
+ "in"; pat = [ IDENT "goal" -> `Goal | IDENT "hyp" -> `Everywhere ] ->
+ pat
+ ];
+ terms = LIST0 term SEP SYMBOL "," ->
+ let tac =
+ (match (pat, terms) with
+ | None, [] -> TacticAst.Reduce (kind, None)
+ | None, terms -> TacticAst.Reduce (kind, Some (terms, `Goal))
+ | Some pat, [] -> TacticAst.Reduce (kind, Some ([], pat))
+ | Some pat, terms -> TacticAst.Reduce (kind, Some (terms, pat)))
+ in
+ return_tactic loc tac
+ | [ IDENT "reflexivity" | IDENT "Reflexivity" ] ->
+ return_tactic loc TacticAst.Reflexivity
+ | [ IDENT "replace" | IDENT "Replace" ];
+ t1 = tactic_term; "with"; t2 = tactic_term ->
+ return_tactic loc (TacticAst.Replace (t1, t2))
+ (* TODO Rewrite *)
+ (* TODO Replace_pattern *)
+ | [ IDENT "right" | IDENT "Right" ] -> return_tactic loc TacticAst.Right
+ | [ IDENT "ring" | IDENT "Ring" ] -> return_tactic loc TacticAst.Ring
+ | [ IDENT "split" | IDENT "Split" ] -> return_tactic loc TacticAst.Split
+ | [ IDENT "symmetry" | IDENT "Symmetry" ] ->
+ return_tactic loc TacticAst.Symmetry
+ | [ IDENT "transitivity" | IDENT "Transitivity" ];
+ t = tactic_term ->
+ return_tactic loc (TacticAst.Transitivity t)
+ ]
+ ];
+ tactical0: [ [ t = tactical; SYMBOL "." -> return_tactical loc t ] ];
+ tactical:
+ [ "command" NONA
+ [ cmd = command -> return_tactical loc (TacticAst.Command cmd) ]
+ | "sequence" LEFTA
+ [ tactics = LIST1 NEXT SEP SYMBOL ";" ->
+ (match tactics with
+ | [tactic] -> tactic
+ | _ -> return_tactical loc (TacticAst.Seq tactics))
+ ]
+ | "then" NONA
+ [ tac = tactical;
+ PAREN "["; tacs = LIST0 tactical SEP SYMBOL ";"; PAREN "]" ->
+ return_tactical loc (TacticAst.Then (tac, tacs))
+ ]
+ | "loops" RIGHTA
+ [ [ IDENT "do" | IDENT "Do" ]; count = int; tac = tactical ->
+ return_tactical loc (TacticAst.Do (count, tac))
+ | [ IDENT "repeat" | IDENT "Repeat" ]; tac = tactical ->
+ return_tactical loc (TacticAst.Repeat tac)
+ ]
+ | "simple" NONA
+ [ [ IDENT "tries" | IDENT "Tries" ];
+ PAREN "["; tacs = LIST0 tactical SEP SYMBOL ";"; PAREN "]" ->
+ return_tactical loc (TacticAst.Tries tacs)
+ | [ IDENT "try" | IDENT "Try" ]; tac = NEXT ->
+ return_tactical loc (TacticAst.Try tac)
+ | [ IDENT "fail" | IDENT "Fail" ] -> return_tactical loc TacticAst.Fail
+ | [ IDENT "id" | IDENT "Id" ] -> return_tactical loc TacticAst.IdTac
+ | PAREN "("; tac = tactical; PAREN ")" -> return_tactical loc tac
+ | tac = tactic -> return_tactical loc (TacticAst.Tactic tac)
+ ]
+ ];
+ theorem_flavour: [ (* all flavours but Goal *)
+ [ [ IDENT "definition" | IDENT "Definition" ] -> `Definition
+ | [ IDENT "fact" | IDENT "Fact" ] -> `Fact
+ | [ IDENT "lemma" | IDENT "Lemma" ] -> `Lemma
+ | [ IDENT "remark" | IDENT "Remark" ] -> `Remark
+ | [ IDENT "theorem" | IDENT "Theorem" ] -> `Theorem
+ ]
+ ];
+ inductive_spec: [ [
+ fst_name = IDENT; params = LIST0 [
+ PAREN "("; names = LIST1 IDENT SEP SYMBOL ","; SYMBOL ":";
+ typ = term; PAREN ")" -> (names, typ) ];
+ 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)
+ ] ];
+ print_kind: [
+ [ [ IDENT "Env" | IDENT "env" | IDENT "Environment" | IDENT "environment" ]
+ -> `Env
+ | [ IDENT "Coer" | IDENT "coer" | IDENT "Coercions" | IDENT "coercions" ]
+ -> `Coer
+ ] ];
+
+ command: [
+ [ [ IDENT "abort" | IDENT "Abort" ] -> return_command loc TacticAst.Abort
+ | [ IDENT "proof" | IDENT "Proof" ] -> return_command loc TacticAst.Proof
+ | [ IDENT "quit" | IDENT "Quit" ] -> return_command loc TacticAst.Quit
+ | [ IDENT "qed" | IDENT "Qed" ] ->
+ return_command loc (TacticAst.Qed None)
+ | [ IDENT "print" | IDENT "Print" ];
+ print_kind = print_kind ->
+ return_command loc (TacticAst.Print print_kind)
+ | [ IDENT "save" | IDENT "Save" ]; name = IDENT ->
+ return_command loc (TacticAst.Qed (Some name))
+ | flavour = theorem_flavour; name = OPT IDENT; SYMBOL ":"; typ = term;
+ body = OPT [ SYMBOL <:unicode<def>> (* ≝ *); body = term -> body ] ->
+ return_command loc (TacticAst.Theorem (flavour, name, typ, body))
+ | "let"; ind_kind = [ "corec" -> `CoInductive | "rec"-> `Inductive ];
+ defs = let_defs ->
+ let name,ty =
+ match defs with
+ | ((Cic.Name name,Some ty),_,_) :: _ -> name,ty
+ | ((Cic.Name name,None),_,_) :: _ ->
+ fail loc ("No type given for " ^ name)
+ | _ -> assert false
+ in
+ let body = CicAst.Ident (name,None) in
+ TacticAst.Theorem(`Definition, Some name, ty,
+ Some (CicAst.LetRec (ind_kind, defs, body)))
+
+ | [ IDENT "inductive" | IDENT "Inductive" ]; spec = inductive_spec ->
+ let (params, ind_types) = spec in
+ return_command loc (TacticAst.Inductive (params, ind_types))
+ | [ IDENT "coinductive" | 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
+ return_command loc (TacticAst.Inductive (params, ind_types))
+ | [ IDENT "coercion" | IDENT "Coercion" ] ; name = IDENT ->
+ return_command loc (TacticAst.Coercion (CicAst.Ident (name,Some [])))
+ | [ IDENT "coercion" | IDENT "Coercion" ] ; name = URI ->
+ return_command loc (TacticAst.Coercion (CicAst.Uri (name,Some [])))
+ | [ IDENT "goal" | IDENT "Goal" ]; typ = term;
+ body = OPT [ SYMBOL <:unicode<def>> (* ≝ *); body = term -> body ] ->
+ return_command loc (TacticAst.Theorem (`Goal, None, typ, body))
+ | [ IDENT "undo" | IDENT "Undo" ]; steps = OPT NUM ->
+ return_command loc (TacticAst.Undo (int_opt steps))
+ | [ IDENT "redo" | IDENT "Redo" ]; steps = OPT NUM ->
+ return_command loc (TacticAst.Redo (int_opt steps))
+ | [ IDENT "baseuri" | IDENT "Baseuri" ]; uri = OPT QSTRING ->
+ return_command loc (TacticAst.Baseuri uri)
+ | [ IDENT "basedir" | IDENT "Basedir" ]; uri = OPT QSTRING ->
+ return_command loc (TacticAst.Basedir uri)
+ | [ IDENT "check" | IDENT "Check" ]; t = term ->
+ return_command loc (TacticAst.Check t)
+(*
+ | [ IDENT "alias" | IDENT "Alias" ]; spec = alias_spec ->
+ return_command loc (TacticAst.Alias spec)
+*)
+ ]
+ ];
+ script_entry: [
+ [ cmd = tactical0 -> Command cmd
+(* | s = COMMENT -> Comment (loc, s) *)
+ ]
+ ];
+ script: [ [ entries = LIST0 script_entry; EOI -> (loc, entries) ] ];
END
-let parse_term stream =
+let exc_located_wrapper f =
try
- Grammar.Entry.parse term0 stream
- with Stdpp.Exc_located ((x, y), exn) ->
- raise (Parse_error (sprintf "parse error at characters %d-%d: %s" x y
- (Printexc.to_string exn)))
+ f ()
+ with
+ | Stdpp.Exc_located (floc, Stream.Error msg) ->
+ raise (Parse_error (floc, msg))
+ | Stdpp.Exc_located (floc, exn) ->
+ raise (Parse_error (floc, (Printexc.to_string exn)))
+
+let parse_term stream =
+ exc_located_wrapper (fun () -> (Grammar.Entry.parse term0 stream))
+let parse_tactic stream =
+ exc_located_wrapper (fun () -> (Grammar.Entry.parse tactic stream))
+let parse_tactical stream =
+ exc_located_wrapper (fun () -> (Grammar.Entry.parse tactical0 stream))
+let parse_script stream =
+ exc_located_wrapper (fun () -> (Grammar.Entry.parse script stream))
(**/**)
(** {2 Interface for gTopLevel} *)
-open DisambiguateTypes
-
module EnvironmentP3 =
struct
type t = environment
let empty = ""
- let aliases_grammar = Grammar.gcreate CicTextualLexer2.cic_lexer
+ let aliases_grammar = Grammar.gcreate cic_lexer
let aliases = Grammar.Entry.create aliases_grammar "aliases"
let to_string env =
if s = empty then
Environment.empty
else
- try
- Grammar.Entry.parse aliases (Stream.of_string s)
- with Stdpp.Exc_located ((x, y), exn) ->
- raise (Parse_error (sprintf "parse error at characters %d-%d: %s" x y
- (Printexc.to_string exn)))
+ exc_located_wrapper
+ (fun () -> Grammar.Entry.parse aliases (Stream.of_string s))
end
+(* vim:set encoding=utf8: *)