1 files changed, 0 insertions, 311 deletions

diff --git a/plugins/syntax/numbers_syntax.ml b/plugins/syntax/numbers_syntax.ml
deleted file mode 100644
index f65f9b79..00000000
--- a/plugins/syntax/numbers_syntax.ml
+++ /dev/null
@@ -1,311 +0,0 @@
-(************************************************************************)
-(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
-(* <O___,, *   INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016     *)
-(*   \VV/  **************************************************************)
-(*    //   *      This file is distributed under the terms of the       *)
-(*         *       GNU Lesser General Public License Version 2.1        *)
-(************************************************************************)
-
-(* Poor's man DECLARE PLUGIN *)
-let __coq_plugin_name = "numbers_syntax_plugin"
-let () = Mltop.add_known_module __coq_plugin_name
-
-(* digit-based syntax for int31, bigN bigZ and bigQ *)
-
-open Bigint
-open Names
-open Globnames
-open Glob_term
-
-(*** Constants for locating int31 / bigN / bigZ / bigQ constructors ***)
-
-let make_dir l = DirPath.make (List.rev_map Id.of_string l)
-let make_path dir id = Libnames.make_path (make_dir dir) (Id.of_string id)
-
-let make_mind mp id = Names.MutInd.make2 mp (Label.make id)
-let make_mind_mpfile dir id = make_mind (MPfile (make_dir dir)) id
-let make_mind_mpdot dir modname id =
-  let mp = MPdot (MPfile (make_dir dir), Label.make modname)
-  in make_mind mp id
-
-
-(* int31 stuff *)
-let int31_module = ["Coq"; "Numbers"; "Cyclic"; "Int31"; "Int31"]
-let int31_path = make_path int31_module "int31"
-let int31_id = make_mind_mpfile int31_module
-let int31_scope = "int31_scope"
-
-let int31_construct = ConstructRef ((int31_id "int31",0),1)
-
-let int31_0 = ConstructRef ((int31_id "digits",0),1)
-let int31_1 = ConstructRef ((int31_id "digits",0),2)
-
-
-(* bigN stuff*)
-let zn2z_module = ["Coq"; "Numbers"; "Cyclic"; "DoubleCyclic"; "DoubleType"]
-let zn2z_path = make_path zn2z_module "zn2z"
-let zn2z_id = make_mind_mpfile zn2z_module
-
-let zn2z_W0 = ConstructRef ((zn2z_id "zn2z",0),1)
-let zn2z_WW = ConstructRef ((zn2z_id "zn2z",0),2)
-
-let bigN_module = ["Coq"; "Numbers"; "Natural"; "BigN"; "BigN" ]
-let bigN_path = make_path (bigN_module@["BigN"]) "t"
-let bigN_t = make_mind_mpdot bigN_module "BigN" "t'"
-let bigN_scope = "bigN_scope"
-
-(* number of inlined level of bigN (actually the level 0 to n_inlined-1 are inlined) *)
-let n_inlined = 7
-
-let bigN_constructor i =
-  ConstructRef ((bigN_t,0),(min i n_inlined)+1)
-
-(*bigZ stuff*)
-let bigZ_module = ["Coq"; "Numbers"; "Integer"; "BigZ"; "BigZ" ]
-let bigZ_path = make_path (bigZ_module@["BigZ"]) "t"
-let bigZ_t = make_mind_mpdot bigZ_module "BigZ" "t_"
-let bigZ_scope = "bigZ_scope"
-
-let bigZ_pos = ConstructRef ((bigZ_t,0),1)
-let bigZ_neg = ConstructRef ((bigZ_t,0),2)
-
-
-(*bigQ stuff*)
-let bigQ_module = ["Coq"; "Numbers"; "Rational"; "BigQ"; "BigQ"]
-let bigQ_path = make_path (bigQ_module@["BigQ"]) "t"
-let bigQ_t = make_mind_mpdot bigQ_module "BigQ" "t_"
-let bigQ_scope = "bigQ_scope"
-
-let bigQ_z =  ConstructRef ((bigQ_t,0),1)
-
-
-(*** Definition of the Non_closed exception, used in the pretty printing ***)
-exception Non_closed
-
-(*** Parsing for int31 in digital notation ***)
-
-(* parses a *non-negative* integer (from bigint.ml) into an int31
-   wraps modulo 2^31 *)
-let int31_of_pos_bigint dloc n =
-  let ref_construct = GRef (dloc, int31_construct, None) in
-  let ref_0 = GRef (dloc, int31_0, None) in
-  let ref_1 = GRef (dloc, int31_1, None) in
-  let rec args counter n =
-    if counter <= 0 then
-      []
-    else
-      let (q,r) = div2_with_rest n in
-	(if r then ref_1 else ref_0)::(args (counter-1) q)
-  in
-  GApp (dloc, ref_construct, List.rev (args 31 n))
-
-let error_negative dloc =
-  CErrors.user_err_loc (dloc, "interp_int31", Pp.str "int31 are only non-negative numbers.")
-
-let interp_int31 dloc n =
-  if is_pos_or_zero n then
-    int31_of_pos_bigint dloc n
-  else
-    error_negative dloc
-
-(* Pretty prints an int31 *)
-
-let bigint_of_int31 =
-  let rec args_parsing args cur =
-    match args with
-      | [] -> cur
-      | (GRef (_,b,_))::l when eq_gr b int31_0 -> args_parsing l (mult_2 cur)
-      | (GRef (_,b,_))::l when eq_gr b int31_1 -> args_parsing l (add_1 (mult_2 cur))
-      | _ -> raise Non_closed
-  in
-  function
-  | GApp (_, GRef (_, c, _), args) when eq_gr c int31_construct -> args_parsing args zero
-  | _ -> raise Non_closed
-
-let uninterp_int31 i =
-  try
-    Some (bigint_of_int31 i)
-  with Non_closed ->
-    None
-
-(* Actually declares the interpreter for int31 *)
-let _ = Notation.declare_numeral_interpreter int31_scope
-  (int31_path, int31_module)
-  interp_int31
-  ([GRef (Loc.ghost, int31_construct, None)],
-   uninterp_int31,
-   true)
-
-
-(*** Parsing for bigN in digital notation ***)
-(* the base for bigN (in Coq) that is 2^31 in our case *)
-let base = pow two 31
-
-(* base of the bigN of height N : (2^31)^(2^n) *)
-let rank n =
-  let rec rk n pow2 =
-    if n <= 0 then pow2
-    else rk (n-1) (mult pow2 pow2)
-  in rk n base
-
-(* splits a number bi at height n, that is the rest needs 2^n int31 to be stored
-   it is expected to be used only when the quotient would also need 2^n int31 to be
-   stored *)
-let split_at n bi =
-  euclid bi (rank (n-1))
-
-(* search the height of the Coq bigint needed to represent the integer bi *)
-let height bi =
-  let rec hght n pow2 =
-    if less_than bi pow2 then n
-    else hght (n+1) (mult pow2 pow2)
-  in hght 0 base
-
-(* n must be a non-negative integer (from bigint.ml) *)
-let word_of_pos_bigint dloc hght n =
-  let ref_W0 = GRef (dloc, zn2z_W0, None) in
-  let ref_WW = GRef (dloc, zn2z_WW, None) in
-  let rec decomp hgt n =
-    if hgt <= 0 then
-      int31_of_pos_bigint dloc n
-    else if equal n zero then
-      GApp (dloc, ref_W0, [GHole (dloc, Evar_kinds.InternalHole, Misctypes.IntroAnonymous, None)])
-    else
-      let (h,l) = split_at hgt n in
-      GApp (dloc, ref_WW, [GHole (dloc, Evar_kinds.InternalHole, Misctypes.IntroAnonymous, None);
-			   decomp (hgt-1) h;
-			   decomp (hgt-1) l])
-  in
-  decomp hght n
-
-let bigN_of_pos_bigint dloc n =
-  let h = height n in
-  let ref_constructor = GRef (dloc, bigN_constructor h, None) in
-  let word = word_of_pos_bigint dloc h n in
-  let args =
-    if h < n_inlined then [word]
-    else [Nat_syntax_plugin.Nat_syntax.nat_of_int dloc (of_int (h-n_inlined));word]
-  in
-  GApp (dloc, ref_constructor, args)
-
-let bigN_error_negative dloc =
-  CErrors.user_err_loc (dloc, "interp_bigN", Pp.str "bigN are only non-negative numbers.")
-
-let interp_bigN dloc n =
-  if is_pos_or_zero n then
-    bigN_of_pos_bigint dloc n
-  else
-    bigN_error_negative dloc
-
-
-(* Pretty prints a bigN *)
-
-let bigint_of_word =
-  let rec get_height rc =
-    match rc with
-    | GApp (_,GRef(_,c,_), [_;lft;rght]) when eq_gr c zn2z_WW ->
-      1+max (get_height lft) (get_height rght)
-    | _ -> 0
-  in
-  let rec transform hght rc =
-    match rc with
-    | GApp (_,GRef(_,c,_),_) when eq_gr c zn2z_W0-> zero
-    | GApp (_,GRef(_,c,_), [_;lft;rght]) when eq_gr c zn2z_WW->
-      let new_hght = hght-1 in
-      add (mult (rank new_hght)
-             (transform new_hght lft))
-	(transform new_hght rght)
-    | _ -> bigint_of_int31 rc
-  in
-  fun rc ->
-    let hght = get_height rc in
-    transform hght rc
-
-let bigint_of_bigN rc =
-  match rc with
-  | GApp (_,_,[one_arg]) -> bigint_of_word one_arg
-  | GApp (_,_,[_;second_arg]) -> bigint_of_word second_arg
-  | _ -> raise Non_closed
-
-let uninterp_bigN rc =
-  try
-    Some (bigint_of_bigN rc)
-  with Non_closed ->
-    None
-
-
-(* declare the list of constructors of bigN used in the declaration of the
-   numeral interpreter *)
-
-let bigN_list_of_constructors =
-  let rec build i =
-    if i < n_inlined+1 then
-      GRef (Loc.ghost, bigN_constructor i,None)::(build (i+1))
-    else
-      []
-  in
-  build 0
-
-(* Actually declares the interpreter for bigN *)
-let _ = Notation.declare_numeral_interpreter bigN_scope
-  (bigN_path, bigN_module)
-  interp_bigN
-  (bigN_list_of_constructors,
-   uninterp_bigN,
-   true)
-
-
-(*** Parsing for bigZ in digital notation ***)
-let interp_bigZ dloc n =
-  let ref_pos = GRef (dloc, bigZ_pos, None) in
-  let ref_neg = GRef (dloc, bigZ_neg, None) in
-  if is_pos_or_zero n then
-    GApp (dloc, ref_pos, [bigN_of_pos_bigint dloc n])
-  else
-    GApp (dloc, ref_neg, [bigN_of_pos_bigint dloc (neg n)])
-
-(* pretty printing functions for bigZ *)
-let bigint_of_bigZ = function
-  | GApp (_, GRef(_,c,_), [one_arg]) when eq_gr c bigZ_pos -> bigint_of_bigN one_arg
-  | GApp (_, GRef(_,c,_), [one_arg]) when eq_gr c bigZ_neg ->
-      let opp_val = bigint_of_bigN one_arg in
-      if equal opp_val zero then
-	raise Non_closed
-      else
-	neg opp_val
-  | _ -> raise Non_closed
-
-
-let uninterp_bigZ rc =
-  try
-    Some (bigint_of_bigZ rc)
-  with Non_closed ->
-    None
-
-(* Actually declares the interpreter for bigZ *)
-let _ = Notation.declare_numeral_interpreter bigZ_scope
-  (bigZ_path, bigZ_module)
-  interp_bigZ
-  ([GRef (Loc.ghost, bigZ_pos, None);
-    GRef (Loc.ghost, bigZ_neg, None)],
-   uninterp_bigZ,
-   true)
-
-(*** Parsing for bigQ in digital notation ***)
-let interp_bigQ dloc n =
-  let ref_z = GRef (dloc, bigQ_z, None) in
-  GApp (dloc, ref_z, [interp_bigZ dloc n])
-
-let uninterp_bigQ rc =
-  try match rc with
-    | GApp (_, GRef(_,c,_), [one_arg]) when eq_gr c bigQ_z ->
-	Some (bigint_of_bigZ one_arg)
-    | _ -> None (* we don't pretty-print yet fractions *)
-  with Non_closed -> None
-
-(* Actually declares the interpreter for bigQ *)
-let _ = Notation.declare_numeral_interpreter bigQ_scope
-  (bigQ_path, bigQ_module)
-  interp_bigQ
-  ([GRef (Loc.ghost, bigQ_z, None)], uninterp_bigQ,
-   true)