clarified background_foundation vs. theory_foundation (with const_declaration);
(* Title: Pure/Isar/named_target.ML
Author: Makarius
Author: Florian Haftmann, TU Muenchen
Targets for theory, locale, class -- at the bottom the nested structure.
*)
signature NAMED_TARGET =
sig
val peek: local_theory -> {target: string, is_locale: bool, is_class: bool} option
val init: (local_theory -> local_theory) -> string -> theory -> local_theory
val theory_init: theory -> local_theory
val reinit: local_theory -> local_theory -> local_theory
val context_cmd: xstring * Position.T -> theory -> local_theory
end;
structure Named_Target: NAMED_TARGET =
struct
(* context data *)
datatype target =
Target of {target: string, is_locale: bool, is_class: bool,
before_exit: local_theory -> local_theory};
fun make_target target is_locale is_class before_exit =
Target {target = target, is_locale = is_locale, is_class = is_class,
before_exit = before_exit};
fun named_target _ "" before_exit = make_target "" false false before_exit
| named_target thy locale before_exit =
if Locale.defined thy locale
then make_target locale true (Class.is_class thy locale) before_exit
else error ("No such locale: " ^ quote locale);
structure Data = Proof_Data
(
type T = target option;
fun init _ = NONE;
);
val peek =
Data.get #> Option.map (fn Target {target, is_locale, is_class, ...} =>
{target = target, is_locale = is_locale, is_class = is_class});
(* consts in locale *)
fun locale_const (Target {target, is_class, ...}) prmode ((b, mx), rhs) =
Generic_Target.locale_declaration target true (fn phi =>
let
val b' = Morphism.binding phi b;
val rhs' = Morphism.term phi rhs;
val same_shape = Term.aconv_untyped (rhs, rhs');
(* FIXME workaround based on educated guess *)
val prefix' = Binding.prefix_of b';
val is_canonical_class = is_class andalso
(Binding.eq_name (b, b')
andalso not (null prefix')
andalso List.last prefix' = (Class.class_prefix target, false)
orelse same_shape);
in
not is_canonical_class ?
Generic_Target.generic_const same_shape prmode ((b', mx), Term.close_schematic_term rhs')
end) #>
(fn lthy => lthy |> Generic_Target.const_declaration
(fn level => level <> 0 andalso level <> Local_Theory.level lthy) prmode ((b, mx), rhs));
(* define *)
fun locale_foundation ta (((b, U), mx), (b_def, rhs)) (type_params, term_params) =
Generic_Target.background_foundation (((b, U), NoSyn), (b_def, rhs)) (type_params, term_params)
#-> (fn (lhs, def) => locale_const ta Syntax.mode_default ((b, mx), lhs)
#> pair (lhs, def));
fun class_foundation (ta as Target {target, ...})
(((b, U), mx), (b_def, rhs)) (type_params, term_params) =
Generic_Target.background_foundation (((b, U), NoSyn), (b_def, rhs)) (type_params, term_params)
#-> (fn (lhs, def) => locale_const ta Syntax.mode_default ((b, NoSyn), lhs)
#> Class.const target ((b, mx), (type_params, lhs))
#> pair (lhs, def));
fun target_foundation (ta as Target {is_locale, is_class, ...}) =
if is_class then class_foundation ta
else if is_locale then locale_foundation ta
else Generic_Target.theory_foundation;
(* notes *)
fun target_notes (Target {target, is_locale, ...}) =
if is_locale then Generic_Target.locale_notes target
else Generic_Target.theory_notes;
(* abbrev *)
fun locale_abbrev ta prmode ((b, mx), t) xs =
Local_Theory.background_theory_result
(Sign.add_abbrev Print_Mode.internal (b, t)) #->
(fn (lhs, _) => locale_const ta prmode
((b, mx), Term.list_comb (Logic.unvarify_global lhs, xs)));
fun target_abbrev (ta as Target {target, is_locale, is_class, ...})
prmode (b, mx) (global_rhs, t') xs lthy =
if is_locale then
lthy
|> locale_abbrev ta prmode ((b, if is_class then NoSyn else mx), global_rhs) xs
|> is_class ? Class.abbrev target prmode ((b, mx), t')
else
lthy
|> Generic_Target.theory_abbrev prmode ((b, mx), global_rhs);
(* declaration *)
fun target_declaration (Target {target, ...}) {syntax, pervasive} decl lthy =
if target = "" then Generic_Target.theory_declaration decl lthy
else
lthy
|> pervasive ? Generic_Target.background_declaration decl
|> Generic_Target.locale_declaration target syntax decl
|> (fn lthy' => lthy' |> Generic_Target.standard_declaration (fn level => level <> 0) decl);
(* pretty *)
fun pretty (Target {target, is_locale, is_class, ...}) ctxt =
let
val thy = Proof_Context.theory_of ctxt;
val target_name =
[Pretty.command (if is_class then "class" else "locale"),
Pretty.str (" " ^ Locale.extern thy target)];
val fixes =
map (fn (x, T) => (Binding.name x, SOME T, NoSyn))
(#1 (Proof_Context.inferred_fixes ctxt));
val assumes =
map (fn A => (Attrib.empty_binding, [(Thm.term_of A, [])]))
(Assumption.all_assms_of ctxt);
val elems =
(if null fixes then [] else [Element.Fixes fixes]) @
(if null assumes then [] else [Element.Assumes assumes]);
val body_elems =
if not is_locale then []
else if null elems then [Pretty.block target_name]
else [Pretty.block (Pretty.fbreaks (Pretty.block (target_name @ [Pretty.str " ="]) ::
map (Pretty.chunks o Element.pretty_ctxt ctxt) elems))];
in
Pretty.block [Pretty.command "theory", Pretty.brk 1,
Pretty.str (Context.theory_name (Proof_Context.theory_of ctxt))] :: body_elems
end;
(* init *)
fun init_context (Target {target, is_locale, is_class, ...}) =
if not is_locale then Proof_Context.init_global
else if not is_class then Locale.init target
else Class.init target;
fun init before_exit target thy =
let
val ta = named_target thy target before_exit;
val naming = Sign.naming_of thy
|> Name_Space.mandatory_path (Long_Name.base_name target);
in
thy
|> init_context ta
|> Data.put (SOME ta)
|> Local_Theory.init naming
{define = Generic_Target.define (target_foundation ta),
notes = Generic_Target.notes (target_notes ta),
abbrev = Generic_Target.abbrev (target_abbrev ta),
declaration = target_declaration ta,
pretty = pretty ta,
exit = Local_Theory.target_of o before_exit}
end;
val theory_init = init I "";
val reinit =
Local_Theory.assert_bottom true #> Data.get #> the #>
(fn Target {target, before_exit, ...} => Local_Theory.exit_global #> init before_exit target);
fun context_cmd ("-", _) thy = theory_init thy
| context_cmd target thy = init I (Locale.check thy target) thy;
end;