(* Title: Pure/Tools/class_package.ML
ID: $Id$
Author: Florian Haftmann, TU Muenchen
Type classes derived from primitive axclasses and locales.
*)
signature CLASS_PACKAGE =
sig
val class: bstring -> class list -> Element.context list -> theory
-> ProofContext.context * theory
val class_i: bstring -> class list -> Element.context_i list -> theory
-> ProofContext.context * theory
val instance_arity: (xstring * string list) * string
-> bstring * Attrib.src list -> ((bstring * Attrib.src list) * string) list
-> theory -> Proof.state
val instance_arity_i: (string * sort list) * sort
-> bstring * attribute list -> ((bstring * attribute list) * term) list
-> theory -> Proof.state
val prove_instance_arity: tactic -> (string * sort list) * sort
-> bstring * attribute list -> ((bstring * attribute list) * term) list
-> theory -> theory
val instance_sort: string * string -> theory -> Proof.state
val instance_sort_i: class * sort -> theory -> Proof.state
val prove_instance_sort: tactic -> class * sort -> theory -> theory
val use_cp_instance: bool ref;
val intern_class: theory -> xstring -> class
val intern_sort: theory -> sort -> sort
val extern_class: theory -> class -> xstring
val extern_sort: theory -> sort -> sort
val certify_class: theory -> class -> class
val certify_sort: theory -> sort -> sort
val read_sort: theory -> string -> sort
val operational_sort_of: theory -> sort -> sort
val the_superclasses: theory -> class -> class list
val the_consts_sign: theory -> class -> string * (string * typ) list
val lookup_const_class: theory -> string -> class option
val the_instances: theory -> class -> (string * ((sort list) * string)) list
val the_inst_sign: theory -> class * string -> (string * sort) list * (string * typ) list
val get_classtab: theory -> (string * string) list Symtab.table
val print_classes: theory -> unit
val intro_classes_tac: thm list -> tactic
val default_intro_classes_tac: thm list -> tactic
type sortcontext = (string * sort) list
datatype classlookup = Instance of (class * string) * classlookup list list
| Lookup of class list * (string * (int * int))
val extract_sortctxt: theory -> typ -> sortcontext
val extract_classlookup: theory -> string * typ -> classlookup list list
val extract_classlookup_inst: theory -> class * string -> class -> classlookup list list
val extract_classlookup_member: theory -> typ * typ -> classlookup list list
end;
structure ClassPackage: CLASS_PACKAGE =
struct
(* theory data *)
datatype class_data = ClassData of {
name_locale: string,
name_axclass: string,
intro: thm option,
var: string,
consts: (string * (string * typ)) list
(*locale parameter ~> toplevel const*)
};
fun rep_classdata (ClassData c) = c;
fun eq_classdata (ClassData {
name_locale = name_locale1, name_axclass = name_axclass1, intro = intro1,
var = var1, consts = consts1}, ClassData {
name_locale = name_locale2, name_axclass = name_axclass2, intro = intro2,
var = var2, consts = consts2}) =
name_locale1 = name_locale2 andalso name_axclass1 = name_axclass2
andalso eq_opt eq_thm (intro1, intro2) andalso var1 = var2
andalso eq_list (eq_pair (op =) (eq_pair (op =) (Type.eq_type Vartab.empty)))
(consts1, consts2);
structure ClassData = TheoryDataFun (
struct
val name = "Pure/classes";
type T = (class_data Graph.T
* (string * (sort list * string)) list Symtab.table)
(*class ~> tyco ~> (arity, thyname)*)
* class Symtab.table;
val empty = ((Graph.empty, Symtab.empty), Symtab.empty);
val copy = I;
val extend = I;
fun merge _ (((g1, c1), f1) : T, ((g2, c2), f2)) =
((Graph.merge eq_classdata (g1, g2), Symtab.join (fn _ => AList.merge (op =) (op =)) (c1, c2)),
Symtab.merge (op =) (f1, f2));
fun print thy ((gr, _), _) =
let
fun pretty_class gr (name, ClassData {name_locale, name_axclass, intro, var, consts}) =
(Pretty.block o Pretty.fbreaks) [
Pretty.str ("class " ^ name ^ ":"),
(Pretty.block o Pretty.fbreaks) (
Pretty.str "superclasses: "
:: (map Pretty.str o Graph.imm_succs gr) name
),
Pretty.str ("locale: " ^ name_locale),
Pretty.str ("axclass: " ^ name_axclass),
Pretty.str ("class variable: " ^ var),
(Pretty.block o Pretty.fbreaks) (
Pretty.str "constants: "
:: map (fn (_, (c, ty)) => Pretty.str (c ^ " :: " ^ Sign.string_of_typ thy ty)) consts
)
]
in
(Pretty.writeln o Pretty.chunks o map (pretty_class gr)
o AList.make (Graph.get_node gr) o flat o Graph.strong_conn) gr
end;
end
);
val _ = Context.add_setup ClassData.init;
val print_classes = ClassData.print;
(* queries *)
val lookup_class_data = Option.map rep_classdata oo try o Graph.get_node o fst o fst o ClassData.get;
val the_instances = these oo Symtab.lookup o snd o fst o ClassData.get;
val lookup_const_class = Symtab.lookup o snd o ClassData.get;
fun the_class_data thy class =
case lookup_class_data thy class
of NONE => error ("undeclared operational class " ^ quote class)
| SOME data => data;
val is_class = is_some oo lookup_class_data;
fun is_operational_class thy cls =
lookup_class_data thy cls
|> Option.map (not o null o #consts)
|> the_default false;
fun operational_sort_of thy sort =
let
fun get_sort class =
if is_operational_class thy class
then [class]
else operational_sort_of thy (Sign.super_classes thy class);
in
map get_sort sort
|> flat
|> Sign.certify_sort thy
end;
fun the_superclasses thy class =
if is_class thy class
then
Sign.super_classes thy class
|> operational_sort_of thy
else
error ("no class: " ^ class);
fun get_superclass_derivation thy (subclass, superclass) =
if subclass = superclass
then SOME [subclass]
else case Graph.find_paths ((fst o fst o ClassData.get) thy) (subclass, superclass)
of [] => NONE
| (p::_) => (SOME o filter (is_operational_class thy)) p;
fun the_ancestry thy classes =
let
fun ancestry class anc =
anc
|> cons class
|> fold ancestry (the_superclasses thy class);
in fold ancestry classes [] end;
fun the_intros thy =
let
val gr = (fst o fst o ClassData.get) thy;
in (List.mapPartial (#intro o rep_classdata o Graph.get_node gr) o Graph.keys) gr end;
fun subst_clsvar v ty_subst =
map_type_tfree (fn u as (w, _) =>
if w = v then ty_subst else TFree u);
fun the_parm_map thy class =
let
val data = the_class_data thy class
in (#consts data) end;
fun the_consts_sign thy class =
let
val data = the_class_data thy class
in (#var data, (map snd o #consts) data) end;
fun the_inst_sign thy (class, tyco) =
let
val _ = if is_operational_class thy class then () else error ("no operational class: " ^ class);
val arity = Sign.arity_sorts thy tyco [class];
val clsvar = (#var o the_class_data thy) class;
val const_sign = (snd o the_consts_sign thy) class;
fun add_var sort used =
let
val v = hd (Term.invent_names used "'a" 1)
in ((v, sort), v::used) end;
val (vsorts, _) =
[clsvar]
|> fold (fn (_, ty) => curry (gen_union (op =))
((map (fst o fst) o typ_tvars) ty @ (map fst o typ_tfrees) ty)) const_sign
|> fold_map add_var arity;
val ty_inst = Type (tyco, map (fn (v, sort) => TVar ((v, 0), sort)) vsorts);
val inst_signs = map (apsnd (subst_clsvar clsvar ty_inst)) const_sign;
in (vsorts, inst_signs) end;
fun get_classtab thy =
(Symtab.map o map)
(fn (tyco, (_, thyname)) => (tyco, thyname)) ((snd o fst o ClassData.get) thy);
(* updaters *)
fun add_class_data (class, (superclasses, name_locale, name_axclass, intro, var, consts)) =
ClassData.map (fn ((gr, tab), consttab) => ((
gr
|> Graph.new_node (class, ClassData {
name_locale = name_locale,
name_axclass = name_axclass,
intro = intro,
var = var,
consts = consts
})
|> fold (curry Graph.add_edge_acyclic class) superclasses,
tab
|> Symtab.update (class, [])),
consttab
|> fold (fn (_, (c, _)) => Symtab.update (c, class)) consts
));
fun add_inst_data (class, inst) =
ClassData.map (fn ((gr, tab), consttab) =>
let
val undef_supclasses = class :: (filter (Symtab.defined tab) (Graph.all_succs gr [class]));
in
((gr, tab |> fold (fn class => Symtab.map_entry class (AList.update (op =) inst)) undef_supclasses), consttab)
end);
(* name handling *)
fun certify_class thy class =
(fn class => (the_class_data thy class; class)) (Sign.certify_class thy class);
fun certify_sort thy sort =
map (fn class => (the_class_data thy class; class)) (Sign.certify_sort thy sort);
fun intern_class thy =
certify_class thy o Sign.intern_class thy;
fun intern_sort thy =
certify_sort thy o Sign.intern_sort thy;
fun extern_class thy =
Sign.extern_class thy o certify_class thy;
fun extern_sort thy =
Sign.extern_sort thy o certify_sort thy;
fun read_sort thy =
certify_sort thy o Sign.read_sort thy;
(* tactics and methods *)
fun class_intros thy =
AxClass.class_intros thy @ the_intros thy;
fun intro_classes_tac facts st =
(ALLGOALS (Method.insert_tac facts THEN'
REPEAT_ALL_NEW (resolve_tac (class_intros (Thm.theory_of_thm st))))
THEN Tactic.distinct_subgoals_tac) st;
fun default_intro_classes_tac [] = intro_classes_tac []
| default_intro_classes_tac _ = Tactical.no_tac; (*no error message!*)
fun default_tac rules ctxt facts =
HEADGOAL (Method.some_rule_tac rules ctxt facts) ORELSE
default_intro_classes_tac facts;
val _ = Context.add_setup (Method.add_methods
[("intro_classes", Method.no_args (Method.METHOD intro_classes_tac),
"back-chain introduction rules of classes"),
("default", Method.thms_ctxt_args (Method.METHOD oo default_tac),
"apply some intro/elim rule")]);
(* axclass instances *)
local
fun gen_instance mk_prop add_thm after_qed inst thy =
thy
|> ProofContext.init
|> Proof.theorem_i PureThy.internalK NONE (after_qed oo (fold o fold) add_thm) NONE ("", [])
(map (fn t => (("", []), [(t, ([], []))])) (mk_prop thy inst));
in
val axclass_instance_subclass =
gen_instance (single oo (Logic.mk_classrel oo AxClass.read_classrel)) AxClass.add_classrel I;
val axclass_instance_arity =
gen_instance (Logic.mk_arities oo Sign.read_arity) AxClass.add_arity;
val axclass_instance_arity_i =
gen_instance (Logic.mk_arities oo Sign.cert_arity) AxClass.add_arity;
end;
(* classes and instances *)
local
fun intro_incr thy name expr =
let
fun fish_thm basename =
try (PureThy.get_thm thy) ((Name o NameSpace.append basename) "intro");
in if expr = Locale.empty
then fish_thm name
else fish_thm (name ^ "_axioms")
end;
fun add_locale name expr body thy =
thy
|> Locale.add_locale true name expr body
||>> `(fn thy => intro_incr thy name expr)
|-> (fn ((name, ctxt), intro) => pair ((name, intro), ctxt));
fun add_locale_i name expr body thy =
thy
|> Locale.add_locale_i true name expr body
||>> `(fn thy => intro_incr thy name expr)
|-> (fn ((name, ctxt), intro) => pair ((name, intro), ctxt));
fun add_axclass_i (name, supsort) axs thy =
let
val (c, thy') = thy
|> AxClass.add_axclass_i (name, supsort) [] axs;
val {intro, axioms, ...} = AxClass.get_info thy' c;
in ((c, (intro, axioms)), thy') end;
fun prove_interpretation_i (prfx, atts) expr insts tac thy =
let
fun ad_hoc_term NONE = NONE
| ad_hoc_term (SOME (Const (c, ty))) =
let
val p = setmp show_types true (setmp show_sorts true (setmp print_mode [] (Sign.pretty_typ thy))) ty;
val s = c ^ "::" ^ Pretty.output p;
val _ = writeln s;
in SOME s end
| ad_hoc_term (SOME t) =
let
val p = setmp show_types true (setmp show_sorts true (setmp print_mode [] (Sign.pretty_term thy))) t;
val s = Pretty.output p;
val _ = writeln s;
in SOME s end;
in
thy
|> Locale.interpretation (prfx, atts) expr (map ad_hoc_term insts)
|> Proof.global_terminal_proof (Method.Basic (fn _ => Method.SIMPLE_METHOD tac), NONE)
|-> (fn _ => I)
end;
fun gen_class add_locale prep_class bname raw_supclasses raw_elems thy =
let
val supclasses = map (prep_class thy) raw_supclasses;
val supsort =
supclasses
|> map (#name_axclass o the_class_data thy)
|> Sign.certify_sort thy
|> null ? K (Sign.defaultS thy);
val expr = (Locale.Merge o map (Locale.Locale o #name_locale o the_class_data thy)) supclasses;
val mapp_sup = AList.make
(the o AList.lookup (op =) ((flat o map (the_parm_map thy) o the_ancestry thy) supclasses))
((map (fst o fst) o Locale.parameters_of_expr thy) expr);
fun extract_tyvar_consts thy name_locale =
let
fun extract_tyvar_name thy tys =
fold (curry add_typ_tfrees) tys []
|> (fn [(v, sort)] =>
if Sign.subsort thy (supsort, sort)
then v
else error ("illegal sort constraint on class type variable: " ^ Sign.string_of_sort thy sort)
| [] => error ("no class type variable")
| vs => error ("more than one type variable: " ^ (commas o map (Sign.string_of_typ thy o TFree)) vs))
val consts1 =
Locale.parameters_of thy name_locale
|> map (apsnd Syntax.unlocalize_mixfix)
val v = (extract_tyvar_name thy o map (snd o fst)) consts1;
val consts2 = map ((apfst o apsnd) (subst_clsvar v (TFree (v, [])))) consts1;
in (v, chop (length mapp_sup) consts2) end;
fun add_consts v raw_cs_sup raw_cs_this thy =
let
fun add_global_const ((c, ty), syn) thy =
thy
|> Sign.add_consts_i [(c, ty |> subst_clsvar v (TFree (v, Sign.defaultS thy)), syn)]
|> `(fn thy => (c, (Sign.intern_const thy c, ty)))
in
thy
|> fold_map add_global_const raw_cs_this
end;
fun extract_assumes thy name_locale cs_mapp =
let
val subst_assume =
map_aterms (fn Free (c, ty) => Const ((fst o the o AList.lookup (op =) cs_mapp) c, ty)
| t => t)
fun prep_asm ((name, atts), ts) =
((name, map (Attrib.attribute thy) atts), map subst_assume ts)
in
(map prep_asm o Locale.local_asms_of thy) name_locale
end;
fun add_global_constraint v class (_, (c, ty)) thy =
thy
|> Sign.add_const_constraint_i (c, SOME (subst_clsvar v (TFree (v, [class])) ty));
fun mk_const thy class v (c, ty) =
Const (c, subst_clsvar v (TFree (v, [class])) ty);
in
thy
|> add_locale bname expr raw_elems
|-> (fn ((name_locale, intro), ctxt) =>
`(fn thy => extract_tyvar_consts thy name_locale)
#-> (fn (v, (raw_cs_sup, raw_cs_this)) =>
add_consts v raw_cs_sup raw_cs_this
#-> (fn mapp_this =>
`(fn thy => extract_assumes thy name_locale (mapp_sup @ mapp_this))
#-> (fn loc_axioms =>
add_axclass_i (bname, supsort) (map (apfst (apfst (K ""))) loc_axioms)
#-> (fn (name_axclass, (_, ax_axioms)) =>
fold (add_global_constraint v name_axclass) mapp_this
#> add_class_data (name_locale, (supclasses, name_locale, name_axclass, intro, v, mapp_this))
#> prove_interpretation_i (NameSpace.base name_locale, [])
(Locale.Locale name_locale) (map (SOME o mk_const thy name_axclass v) (map snd (mapp_sup @ mapp_this)))
((ALLGOALS o resolve_tac) ax_axioms)
#> pair ctxt
)))))
end;
in
val class = gen_class add_locale intern_class;
val class_i = gen_class add_locale_i certify_class;
end; (* local *)
local
fun gen_add_defs_overloaded prep_att tap_def add_defs tyco raw_defs thy =
let
fun invent_name raw_t =
let
val t = tap_def thy raw_t;
val c = (fst o dest_Const o fst o strip_comb o fst o Logic.dest_equals) t;
in
Thm.def_name (NameSpace.base c ^ "_" ^ NameSpace.base tyco)
end;
fun prep_def (_, (("", a), t)) =
let
val n = invent_name t
in ((n, t), map (prep_att thy) a) end
| prep_def (_, ((n, a), t)) =
((n, t), map (prep_att thy) a);
in
thy
|> add_defs true (map prep_def raw_defs)
end;
val add_defs_overloaded = gen_add_defs_overloaded Attrib.attribute Sign.read_term PureThy.add_defs;
val add_defs_overloaded_i = gen_add_defs_overloaded (K I) (K I) PureThy.add_defs_i;
fun gen_instance_arity prep_arity prep_att add_defs tap_def do_proof raw_arity (raw_name, raw_atts) raw_defs theory =
let
val pp = Sign.pp theory;
val arity as (tyco, asorts, sort) = prep_arity theory ((fn ((x, y), z) => (x, y, z)) raw_arity);
val ty_inst = Type (tyco, map2 (curry TVar o rpair 0) (Term.invent_names [] "'a" (length asorts)) asorts)
val name = case raw_name
of "" => Thm.def_name ((space_implode "_" o map NameSpace.base) sort ^ "_" ^ NameSpace.base tyco)
| _ => raw_name;
val atts = map (prep_att theory) raw_atts;
fun get_classes thy tyco sort =
let
fun get class classes =
if AList.defined (op =) ((the_instances thy) class) tyco
then classes
else classes
|> cons class
|> fold get (the_superclasses thy class)
in fold get sort [] end;
val classes = get_classes theory tyco sort;
val _ = if null classes then error ("already instantiated") else ();
fun get_consts class =
let
val data = the_class_data theory class;
val subst_ty = map_type_tfree (fn (var as (v, _)) =>
if #var data = v then ty_inst else TFree var)
in (map (apsnd subst_ty o snd) o #consts) data end;
val cs = (flat o map get_consts) classes;
fun get_remove_contraint c thy =
let
val ty = Sign.the_const_constraint thy c;
in
thy
|> Sign.add_const_constraint_i (c, NONE)
|> pair (c, Type.unvarifyT ty)
end;
fun check_defs0 thy raw_defs c_req =
let
fun get_c raw_def =
(fst o Sign.cert_def pp o tap_def thy o snd) raw_def;
val c_given = map get_c raw_defs;
fun eq_c ((c1 : string, ty1), (c2, ty2)) =
let
val ty1' = Type.varifyT ty1;
val ty2' = Type.varifyT ty2;
in
c1 = c2
andalso Sign.typ_instance thy (ty1', ty2')
andalso Sign.typ_instance thy (ty2', ty1')
end;
val _ = case subtract eq_c c_req c_given
of [] => ()
| cs => error ("superfluous definition(s) given for "
^ (commas o map (fn (c, ty) => quote (c ^ "::" ^ Sign.string_of_typ thy ty))) cs);
(*val _ = case subtract eq_c c_given c_req
of [] => ()
| cs => error ("no definition(s) given for "
^ (commas o map (fn (c, ty) => quote (c ^ "::" ^ Sign.string_of_typ thy ty))) cs);*)
in () end;
fun check_defs1 raw_defs c_req thy =
let
val thy' = (Sign.add_arities_i [(tyco, asorts, sort)] o Theory.copy) thy
in (check_defs0 thy' raw_defs c_req; thy) end;
fun mangle_alldef_name tyco sort =
Thm.def_name ((space_implode "_" o map NameSpace.base) sort ^ "_" ^ NameSpace.base tyco);
fun note_all tyco sort thms thy =
thy
|> PureThy.note_thmss_i PureThy.internalK [((name, atts), [(thms, [])])]
|> snd;
fun after_qed cs thy =
thy
|> fold (fn class =>
add_inst_data (class, (tyco,
(map (operational_sort_of thy) asorts, Context.theory_name thy)))) sort
|> fold Sign.add_const_constraint_i (map (apsnd SOME) cs);
in
theory
|> check_defs1 raw_defs cs
|> fold_map get_remove_contraint (map fst cs)
||>> add_defs tyco (map (pair NONE) raw_defs)
|-> (fn (cs, defnames) => note_all tyco sort defnames #> pair cs)
|-> (fn cs => do_proof (after_qed cs) arity)
end;
fun instance_arity' do_proof = gen_instance_arity Sign.read_arity Attrib.attribute add_defs_overloaded
(fn thy => fn t => (snd o read_axm thy) ("", t)) do_proof;
fun instance_arity_i' do_proof = gen_instance_arity Sign.cert_arity (K I) add_defs_overloaded_i
(K I) do_proof;
val setup_proof = axclass_instance_arity_i;
fun tactic_proof tac after_qed arity = AxClass.prove_arity arity tac #> after_qed;
in
val instance_arity = instance_arity' setup_proof;
val instance_arity_i = instance_arity_i' setup_proof;
val prove_instance_arity = instance_arity_i' o tactic_proof;
end; (* local *)
local
fun fish_thms (name, expr) after_qed thy =
let
val _ = writeln ("sub " ^ name)
val suplocales = (fn Locale.Merge es => map (fn Locale.Locale n => n) es) expr;
val _ = writeln ("super " ^ commas suplocales)
fun get_c name =
(map (NameSpace.base o fst o fst) o Locale.parameters_of thy) name;
fun get_a name =
(map (NameSpace.base o fst o fst) o Locale.local_asms_of thy) name;
fun get_t supname =
map (NameSpace.append (NameSpace.append name ((space_implode "_" o get_c) supname)) o NameSpace.base)
(get_a name);
val names = map get_t suplocales;
val _ = writeln ("fishing for " ^ (commas o map commas) names);
in
thy
|> after_qed ((map o map) (Drule.standard o get_thm thy o Name) names)
end;
fun add_interpretation_in (after_qed : thm list list -> theory -> theory) (name, expr) thy =
thy
|> Locale.interpretation_in_locale (name, expr);
fun prove_interpretation_in tac (after_qed : thm list list -> theory -> theory) (name, expr) thy =
thy
|> Locale.interpretation_in_locale (name, expr)
|> Proof.global_terminal_proof (Method.Basic (fn _ => Method.SIMPLE_METHOD tac), NONE)
|-> (fn _ => I);
fun gen_instance_sort prep_class prep_sort do_proof (raw_class, raw_sort) theory =
let
val class = prep_class theory raw_class;
val sort = prep_sort theory raw_sort;
val loc_name = (#name_locale o the_class_data theory) class;
val loc_expr =
(Locale.Merge o map (Locale.Locale o #name_locale o the_class_data theory)) sort;
fun after_qed thmss thy =
(writeln "---"; (Pretty.writeln o Display.pretty_thms o flat) thmss; writeln "---"; fold (fn supclass =>
AxClass.prove_classrel (class, supclass)
(ALLGOALS (K (intro_classes_tac [])) THEN
(ALLGOALS o resolve_tac o flat) thmss)
) sort thy)
in
theory
|> do_proof after_qed (loc_name, loc_expr)
end;
fun instance_sort' do_proof = gen_instance_sort intern_class read_sort do_proof;
fun instance_sort_i' do_proof = gen_instance_sort certify_class certify_sort do_proof;
val setup_proof = add_interpretation_in;
val tactic_proof = prove_interpretation_in;
in
val instance_sort = instance_sort' setup_proof;
val instance_sort_i = instance_sort_i' setup_proof;
val prove_instance_sort = instance_sort_i' o tactic_proof;
end; (* local *)
(* extracting dictionary obligations from types *)
type sortcontext = (string * sort) list;
fun extract_sortctxt thy ty =
(typ_tfrees o fst o Type.freeze_thaw_type) ty
|> map (apsnd (operational_sort_of thy))
|> filter (not o null o snd);
datatype classlookup = Instance of (class * string) * classlookup list list
| Lookup of class list * (string * (int * int))
fun pretty_lookup' (Instance ((class, tyco), lss)) =
(Pretty.block o Pretty.breaks) (
Pretty.enum "," "{" "}" [Pretty.str class, Pretty.str tyco]
:: map pretty_lookup lss
)
| pretty_lookup' (Lookup (classes, (v, (i, j)))) =
Pretty.enum " <" "[" "]" (map Pretty.str classes @ [Pretty.str (v ^ "!" ^ string_of_int i ^ "/" ^ string_of_int j)])
and pretty_lookup ls = (Pretty.enum "," "(" ")" o map pretty_lookup') ls;
fun extract_lookup thy sortctxt raw_typ_def raw_typ_use =
let
val typ_def = Type.varifyT raw_typ_def;
val typ_use = Type.varifyT raw_typ_use;
val match_tab = Sign.typ_match thy (typ_def, typ_use) Vartab.empty;
fun tab_lookup vname = (the o Vartab.lookup match_tab) (vname, 0);
fun mk_class_deriv thy subclasses superclass =
let
val (i, (subclass::deriv)) = (the oo get_index) (fn subclass =>
get_superclass_derivation thy (subclass, superclass)
) subclasses;
in (rev deriv, (i, length subclasses)) end;
fun mk_lookup (sort_def, (Type (tyco, tys))) =
map (fn class => Instance ((class, tyco),
map2 (curry mk_lookup)
(map (operational_sort_of thy) (Sign.arity_sorts thy tyco [class]))
tys)
) sort_def
| mk_lookup (sort_def, TVar ((vname, _), sort_use)) =
let
fun mk_look class =
let val (deriv, classindex) = mk_class_deriv thy (operational_sort_of thy sort_use) class
in Lookup (deriv, (vname, classindex)) end;
in map mk_look sort_def end;
in
sortctxt
|> map (tab_lookup o fst)
|> map (apfst (operational_sort_of thy))
|> filter (not o null o fst)
|> map mk_lookup
end;
fun extract_classlookup thy (c, raw_typ_use) =
let
val raw_typ_def = Sign.the_const_constraint thy c;
val typ_def = Type.varifyT raw_typ_def;
fun reorder_sortctxt ctxt =
case lookup_const_class thy c
of NONE => ctxt
| SOME class =>
let
val data = the_class_data thy class;
val sign = (Type.varifyT o the o AList.lookup (op =) ((map snd o #consts) data)) c;
val match_tab = Sign.typ_match thy (sign, typ_def) Vartab.empty;
val v : string = case Vartab.lookup match_tab (#var data, 0)
of SOME (_, TVar ((v, _), _)) => v;
in
(v, (the o AList.lookup (op =) ctxt) v) :: AList.delete (op =) v ctxt
end;
in
extract_lookup thy
(reorder_sortctxt (extract_sortctxt thy ((fst o Type.freeze_thaw_type) raw_typ_def)))
raw_typ_def raw_typ_use
end;
fun extract_classlookup_inst thy (class, tyco) supclass =
let
fun mk_typ class = Type (tyco, (map TFree o fst o the_inst_sign thy) (class, tyco))
val typ_def = mk_typ supclass;
val typ_use = mk_typ class;
in
extract_lookup thy (extract_sortctxt thy typ_def) typ_def typ_use
end;
fun extract_classlookup_member thy (ty_decl, ty_use) =
extract_lookup thy (extract_sortctxt thy ty_decl) ty_decl ty_use;
(* toplevel interface *)
local
structure P = OuterParse
and K = OuterKeyword
in
val (classK, instanceK) = ("class", "instance")
val use_cp_instance = ref false;
fun wrap_add_instance_subclass (class, sort) thy =
case Sign.read_sort thy sort
of [class'] =>
if ! use_cp_instance
andalso (is_some o lookup_class_data thy o Sign.intern_class thy) class
andalso (is_some o lookup_class_data thy o Sign.intern_class thy) class'
then
instance_sort (class, sort) thy
else
axclass_instance_subclass (class, sort) thy
| _ => instance_sort (class, sort) thy;
val parse_inst =
(Scan.optional (P.$$$ "(" |-- P.!!! (P.list1 P.sort --| P.$$$ ")")) [] -- P.xname --| P.$$$ "::" -- P.sort)
>> (fn ((asorts, tyco), sort) => ((tyco, asorts), sort))
|| (P.xname --| P.$$$ "::" -- P.!!! P.arity)
>> (fn (tyco, (asorts, sort)) => ((tyco, asorts), sort));
val locale_val =
(P.locale_expr --
Scan.optional (P.$$$ "+" |-- P.!!! (Scan.repeat1 P.context_element)) [] ||
Scan.repeat1 P.context_element >> pair Locale.empty);
val class_subP = P.name -- Scan.repeat (P.$$$ "+" |-- P.name) >> (op ::);
val class_bodyP = P.!!! (Scan.repeat1 P.context_element);
val classP =
OuterSyntax.command classK "operational type classes" K.thy_decl (
P.name --| P.$$$ "="
-- (
class_subP --| P.$$$ "+" -- class_bodyP
|| class_subP >> rpair []
|| class_bodyP >> pair []
) >> (Toplevel.theory_context
o (fn (bname, (supclasses, elems)) => class bname supclasses elems)));
val instanceP =
OuterSyntax.command instanceK "prove type arity or subclass relation" K.thy_goal ((
P.xname -- ((P.$$$ "\\<subseteq>" || P.$$$ "<") |-- P.!!! P.xname) >> wrap_add_instance_subclass
|| P.opt_thm_name ":" -- (parse_inst -- Scan.repeat (P.opt_thm_name ":" -- P.prop))
>> (fn (("", []), (((tyco, asorts), sort), [])) => axclass_instance_arity I (tyco, asorts, sort)
| (natts, (inst, defs)) => instance_arity inst natts defs)
) >> (Toplevel.print oo Toplevel.theory_to_proof));
val _ = OuterSyntax.add_parsers [classP, instanceP];
end; (* local *)
end; (* struct *)