(* Title: HOL/Tools/numeral.ML
Author: Makarius
Logical and syntactic operations on numerals (see also HOL/Tools/hologic.ML).
*)
signature NUMERAL =
sig
val mk_cnumber: ctyp -> int -> cterm
val mk_number_syntax: int -> term
val dest_num_syntax: term -> int
val add_code: string -> (int -> int) -> (Code_Printer.literals -> int -> string) -> string -> theory -> theory
end;
structure Numeral: NUMERAL =
struct
(* numeral *)
fun dest_num_syntax (Const (\<^const_syntax>\<open>Num.Bit0\<close>, _) $ t) = 2 * dest_num_syntax t
| dest_num_syntax (Const (\<^const_syntax>\<open>Num.Bit1\<close>, _) $ t) = 2 * dest_num_syntax t + 1
| dest_num_syntax (Const (\<^const_syntax>\<open>Num.One\<close>, _)) = 1;
fun mk_num_syntax n =
if n > 0 then
(case IntInf.quotRem (n, 2) of
(0, 1) => Syntax.const \<^const_syntax>\<open>One\<close>
| (n, 0) => Syntax.const \<^const_syntax>\<open>Bit0\<close> $ mk_num_syntax n
| (n, 1) => Syntax.const \<^const_syntax>\<open>Bit1\<close> $ mk_num_syntax n)
else raise Match
fun mk_cbit 0 = \<^cterm>\<open>Num.Bit0\<close>
| mk_cbit 1 = \<^cterm>\<open>Num.Bit1\<close>
| mk_cbit _ = raise CTERM ("mk_cbit", []);
fun mk_cnumeral i =
let
fun mk 1 = \<^cterm>\<open>Num.One\<close>
| mk i =
let val (q, r) = Integer.div_mod i 2 in
Thm.apply (mk_cbit r) (mk q)
end
in
if i > 0 then mk i else raise CTERM ("mk_cnumeral: negative input", [])
end
(* number *)
local
val cterm_of = Thm.cterm_of \<^context>;
fun tvar S = (("'a", 0), S);
val zero_tvar = tvar \<^sort>\<open>zero\<close>;
val zero = cterm_of (Const (\<^const_name>\<open>zero_class.zero\<close>, TVar zero_tvar));
val one_tvar = tvar \<^sort>\<open>one\<close>;
val one = cterm_of (Const (\<^const_name>\<open>one_class.one\<close>, TVar one_tvar));
val numeral_tvar = tvar \<^sort>\<open>numeral\<close>;
val numeral = cterm_of (Const (\<^const_name>\<open>numeral\<close>, \<^typ>\<open>num\<close> --> TVar numeral_tvar));
val uminus_tvar = tvar \<^sort>\<open>uminus\<close>;
val uminus = cterm_of (Const (\<^const_name>\<open>uminus\<close>, TVar uminus_tvar --> TVar uminus_tvar));
fun instT T v = Thm.instantiate_cterm ([(v, T)], []);
in
fun mk_cnumber T 0 = instT T zero_tvar zero
| mk_cnumber T 1 = instT T one_tvar one
| mk_cnumber T i =
if i > 0 then
Thm.apply (instT T numeral_tvar numeral) (mk_cnumeral i)
else
Thm.apply (instT T uminus_tvar uminus)
(Thm.apply (instT T numeral_tvar numeral) (mk_cnumeral (~ i)));
end;
fun mk_number_syntax n =
if n = 0 then Syntax.const \<^const_syntax>\<open>Groups.zero\<close>
else if n = 1 then Syntax.const \<^const_syntax>\<open>Groups.one\<close>
else Syntax.const \<^const_syntax>\<open>numeral\<close> $ mk_num_syntax n;
(* code generator *)
local open Basic_Code_Thingol in
fun dest_num_code (IConst { sym = Code_Symbol.Constant \<^const_name>\<open>Num.One\<close>, ... }) = SOME 1
| dest_num_code (IConst { sym = Code_Symbol.Constant \<^const_name>\<open>Num.Bit0\<close>, ... } `$ t) =
(case dest_num_code t of
SOME n => SOME (2 * n)
| _ => NONE)
| dest_num_code (IConst { sym = Code_Symbol.Constant \<^const_name>\<open>Num.Bit1\<close>, ... } `$ t) =
(case dest_num_code t of
SOME n => SOME (2 * n + 1)
| _ => NONE)
| dest_num_code _ = NONE;
fun add_code number_of preproc print target thy =
let
fun pretty literals _ thm _ _ [(t, _)] =
case dest_num_code t of
SOME n => (Code_Printer.str o print literals o preproc) n
| NONE => Code_Printer.eqn_error thy thm "Illegal numeral expression: illegal term";
in
thy |> Code_Target.set_printings (Code_Symbol.Constant (number_of,
[(target, SOME (Code_Printer.complex_const_syntax (1, pretty)))]))
end;
end; (*local*)
end;