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|
(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \VV/ *************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(***********************************************************************)
open Coqast
open Ast
open Pp
open Util
open Names
open Pcoq
open Extend
let get_r_sign loc =
let ast_of_id id = Astterm.globalize_constr (Nvar(loc,id)) in
((ast_of_id (id_of_string "R0"),
ast_of_id (id_of_string "R1"),
ast_of_id (id_of_string "Rplus"),
ast_of_id (id_of_string "NRplus")))
(* Parsing via Grammar *)
let r_of_int n dloc =
let (ast0,ast1,astp,_) = get_r_sign dloc in
let rec mk_r n =
if n <= 0 then
ast0
else if n = 1 then
ast1
else
Node(dloc,"APPLIST", [astp; ast1; mk_r (n-1)])
in
mk_r n
let r_of_string s dloc =
r_of_int (int_of_string s) dloc
let rnumber = create_constr_entry (get_univ "rnatural") "rnumber"
let _ =
Gram.extend rnumber None
[None, None,
[[Gramext.Stoken ("INT", "")],
Gramext.action r_of_string]]
(** pp **)
exception Non_closed_number
let rec int_of_r_rec ast1 astp p =
match p with
| Node (_,"APPLIST", [b; a; c]) when alpha_eq(b,astp) &&
alpha_eq(a,ast1) ->
(int_of_r_rec ast1 astp c)+1
| a when alpha_eq(a,ast1) -> 1
| _ -> raise Non_closed_number
let int_of_r p =
let (_,ast1,astp,_) = get_r_sign dummy_loc in
try
Some (int_of_r_rec ast1 astp p)
with
Non_closed_number -> None
let replace_plus p =
let (_,ast1,_,astnr) = get_r_sign dummy_loc in
ope ("REXPR",[ope("APPLIST", [astnr; ast1; p])])
let r_printer std_pr p =
let (_,ast1,astp,_) = get_r_sign dummy_loc in
match (int_of_r p) with
| Some i -> str (string_of_int (i+1))
| None -> std_pr (replace_plus p)
let r_printer_outside std_pr p =
let (_,ast1,astp,_) = get_r_sign dummy_loc in
match (int_of_r p) with
| Some i -> str "``" ++ str (string_of_int (i+1)) ++ str "``"
| None -> std_pr (replace_plus p)
let _ = Esyntax.Ppprim.add ("r_printer", r_printer)
let _ = Esyntax.Ppprim.add ("r_printer_outside", r_printer_outside)
(**********************************************************************)
(* Parsing via scopes *)
(**********************************************************************)
open Libnames
open Rawterm
open Bignat
let make_dir l = make_dirpath (List.map id_of_string (List.rev l))
let rdefinitions = make_dir ["Coq";"Reals";"Rdefinitions"]
(* TODO: temporary hack *)
let make_path dir id = Libnames.encode_kn dir (id_of_string id)
let glob_R1 = ConstRef (make_path rdefinitions "R1")
let glob_R0 = ConstRef (make_path rdefinitions "R0")
let glob_Ropp = ConstRef (make_path rdefinitions "Ropp")
let glob_Rplus = ConstRef (make_path rdefinitions "Rplus")
let r_of_posint dloc n =
if is_nonzero n then begin
if Options.is_verbose () & less_than (of_string "5000") n then begin
warning ("You may experiment stack overflow and segmentation fault\
\nwhile parsing numbers in R the absolute value of which is\
\ngreater than 5000");
flush_all ()
end;
let ref_R1 = RRef (dloc, glob_R1) in
let ref_Rplus = RRef (dloc, glob_Rplus) in
let rec r_of_strictly_pos n =
if is_one n then
ref_R1
else
RApp(dloc, ref_Rplus, [ref_R1; r_of_strictly_pos (sub_1 n)])
in r_of_strictly_pos n
end
else
RRef (dloc, glob_R0)
let check_required_module loc d =
let d' = List.map id_of_string d in
let dir = make_dirpath (List.rev d') in
if not (Library.library_is_loaded dir) then
user_err_loc (loc,"z_of_int",
str ("Cannot interpret numbers in Z without requiring first module "
^(list_last d)))
let r_of_int dloc z =
check_required_module dloc ["Coq";"Reals";"Rsyntax"];
match z with
| NEG n -> RApp (dloc, RRef(dloc,glob_Ropp), [r_of_posint dloc n])
| POS n -> r_of_posint dloc n
let _ = Symbols.declare_numeral_interpreter "R_scope" (r_of_int,None)
(***********************************************************************)
(* Printers *)
exception Non_closed_number
let bignat_of_pos p =
let (_,one,plus,_) = get_r_sign dummy_loc in
let rec transl = function
| Node (_,"APPLIST",[p; o; a]) when alpha_eq(p,plus) & alpha_eq(o,one)
-> add_1(transl a)
| a when alpha_eq(a,one) -> Bignat.one
| _ -> raise Non_closed_number
in transl p
let bignat_option_of_pos p =
try
Some (bignat_of_pos p)
with Non_closed_number ->
None
let r_printer_Rplus1 p =
match bignat_option_of_pos p with
| Some n -> Some (str (Bignat.to_string (add_1 n)))
| None -> None
let r_printer_Ropp p =
match bignat_option_of_pos p with
| Some n -> Some (str "-" ++ str (Bignat.to_string n))
| None -> None
let r_printer_R1 _ =
Some (int 1)
let r_printer_R0 _ =
Some (int 0)
(* Declare pretty-printers for integers *)
let _ =
Esyntax.declare_primitive_printer "r_printer_Ropp" "R_scope" (r_printer_Ropp)
let _ =
Esyntax.declare_primitive_printer "r_printer_Rplus1" "R_scope" (r_printer_Rplus1)
let _ =
Esyntax.declare_primitive_printer "r_printer_R1" "R_scope" (r_printer_R1)
let _ =
Esyntax.declare_primitive_printer "r_printer_R0" "R_scope" r_printer_R0
|