vague cleanup in arith proof tools setup: deleted dead code, more proper structures, clearer arrangement
(* Title: HOL/Tools/typecopy_package.ML
Author: Florian Haftmann, TU Muenchen
Introducing copies of types using trivial typedefs; datatype-like abstraction.
*)
signature TYPECOPY_PACKAGE =
sig
type info = {
vs: (string * sort) list,
constr: string,
typ: typ,
inject: thm,
proj: string * typ,
proj_def: thm
}
val add_typecopy: binding * string list -> typ -> (binding * binding) option
-> theory -> (string * info) * theory
val get_typecopies: theory -> string list
val get_info: theory -> string -> info option
val interpretation: (string -> theory -> theory) -> theory -> theory
val add_typecopy_default_code: string -> theory -> theory
val print_typecopies: theory -> unit
val setup: theory -> theory
end;
structure TypecopyPackage: TYPECOPY_PACKAGE =
struct
(* theory data *)
type info = {
vs: (string * sort) list,
constr: string,
typ: typ,
inject: thm,
proj: string * typ,
proj_def: thm
};
structure TypecopyData = TheoryDataFun
(
type T = info Symtab.table;
val empty = Symtab.empty;
val copy = I;
val extend = I;
fun merge _ = Symtab.merge (K true);
);
fun print_typecopies thy =
let
val tab = TypecopyData.get thy;
fun mk (tyco, { vs, constr, typ, proj = (proj, _), ... } : info) =
(Pretty.block o Pretty.breaks) [
Syntax.pretty_typ_global thy (Type (tyco, map TFree vs)),
Pretty.str "=",
(Pretty.str o Sign.extern_const thy) constr,
Syntax.pretty_typ_global thy typ,
Pretty.block [Pretty.str "(", (Pretty.str o Sign.extern_const thy) proj, Pretty.str ")"]];
in
(Pretty.writeln o Pretty.block o Pretty.fbreaks)
(Pretty.str "type copies:" :: map mk (Symtab.dest tab))
end;
val get_typecopies = Symtab.keys o TypecopyData.get;
val get_info = Symtab.lookup o TypecopyData.get;
(* interpretation of type copies *)
structure TypecopyInterpretation = InterpretationFun(type T = string val eq = op =);
val interpretation = TypecopyInterpretation.interpretation;
fun add_typecopy (raw_tyco, raw_vs) raw_ty constr_proj thy =
let
val ty = Sign.certify_typ thy raw_ty;
val vs =
AList.make (the_default HOLogic.typeS o AList.lookup (op =) (Term.add_tfreesT ty [])) raw_vs;
val tac = Tactic.rtac UNIV_witness 1;
fun add_info tyco ( { abs_type = ty_abs, rep_type = ty_rep, Abs_name = c_abs,
Rep_name = c_rep, Abs_inject = inject,
Abs_inverse = inverse, ... } : TypedefPackage.info ) thy =
let
val exists_thm =
UNIV_I
|> Drule.instantiate' [SOME (ctyp_of thy (Logic.varifyT ty_rep))] [];
val inject' = inject OF [exists_thm, exists_thm];
val proj_def = inverse OF [exists_thm];
val info = {
vs = vs,
constr = c_abs,
typ = ty_rep,
inject = inject',
proj = (c_rep, ty_abs --> ty_rep),
proj_def = proj_def
};
in
thy
|> (TypecopyData.map o Symtab.update_new) (tyco, info)
|> TypecopyInterpretation.data tyco
|> pair (tyco, info)
end
in
thy
|> TypedefPackage.add_typedef false (SOME raw_tyco) (raw_tyco, map fst vs, NoSyn)
(HOLogic.mk_UNIV ty) (Option.map swap constr_proj) tac
|-> (fn (tyco, info) => add_info tyco info)
end;
(* code generator setup *)
fun add_typecopy_default_code tyco thy =
let
val SOME { constr = constr_name, proj = (proj, _), proj_def = proj_eq, vs = raw_vs,
typ = raw_ty_rep, ... } = get_info thy tyco;
val inst_meet = Sorts.meet_sort_typ (Sign.classes_of thy)
(Logic.varifyT raw_ty_rep, [HOLogic.class_eq]) handle Sorts.CLASS_ERROR _ => I;
val ty_inst = Logic.unvarifyT o inst_meet o Logic.varifyT;
val vs = (map dest_TFree o snd o dest_Type o ty_inst)
(Type (tyco, map TFree raw_vs));
val ty_rep = ty_inst raw_ty_rep;
val SOME { Rep_inject = proj_inject, ... } = TypedefPackage.get_info thy tyco;
val ty_constr = Logic.unvarifyT (Sign.the_const_type thy constr_name);
val constr = (constr_name, ty_constr)
val ty = Type (tyco, map TFree vs);
fun mk_eq ty t_x t_y = Const (@{const_name eq_class.eq}, ty --> ty --> HOLogic.boolT)
$ t_x $ t_y;
fun mk_proj t = Const (proj, ty --> ty_rep) $ t;
val (t_x, t_y) = (Free ("x", ty), Free ("y", ty));
val def_eq = (HOLogic.mk_Trueprop o HOLogic.mk_eq)
(mk_eq ty t_x t_y, HOLogic.mk_eq (mk_proj t_x, mk_proj t_y));
fun mk_eq_refl thy = @{thm HOL.eq_refl}
|> Thm.instantiate
([pairself (Thm.ctyp_of thy) (TVar (("'a", 0), @{sort eq}), Logic.varifyT ty)], [])
|> AxClass.unoverload thy;
in
thy
|> Code.add_datatype [constr]
|> Code.add_eqn proj_eq
|> TheoryTarget.instantiation ([tyco], vs, [HOLogic.class_eq])
|> `(fn lthy => Syntax.check_term lthy def_eq)
|-> (fn def_eq => Specification.definition
(NONE, (Attrib.empty_binding, def_eq)))
|-> (fn (_, (_, def_thm)) =>
Class.prove_instantiation_exit_result Morphism.thm
(fn _ => fn def_thm => Class.intro_classes_tac []
THEN (Simplifier.rewrite_goals_tac
(map Simpdata.mk_eq [def_thm, @{thm eq}, proj_inject]))
THEN ALLGOALS (rtac @{thm refl})) def_thm)
|-> (fn def_thm => Code.add_eqn def_thm)
|> `(fn thy => mk_eq_refl thy)
|-> (fn refl_thm => Code.add_nonlinear_eqn refl_thm)
end;
val setup =
TypecopyInterpretation.init
#> interpretation add_typecopy_default_code
end;