(* Title: Pure/Isar/object_logic.ML
Author: Markus Wenzel, TU Muenchen
Specifics about common object-logics.
*)
signature OBJECT_LOGIC =
sig
val get_base_sort: Proof.context -> sort option
val add_base_sort: sort -> theory -> theory
val add_judgment: binding * typ * mixfix -> theory -> theory
val add_judgment_cmd: binding * string * mixfix -> theory -> theory
val judgment_name: Proof.context -> string
val is_judgment: Proof.context -> term -> bool
val drop_judgment: Proof.context -> term -> term
val fixed_judgment: Proof.context -> string -> term
val ensure_propT: Proof.context -> term -> term
val dest_judgment: Proof.context -> cterm -> cterm
val judgment_conv: Proof.context -> conv -> conv
val is_propositional: Proof.context -> typ -> bool
val elim_concl: Proof.context -> thm -> term option
val declare_atomize: attribute
val declare_rulify: attribute
val atomize_term: Proof.context -> term -> term
val atomize: Proof.context -> conv
val atomize_prems: Proof.context -> conv
val atomize_prems_tac: Proof.context -> int -> tactic
val full_atomize_tac: Proof.context -> int -> tactic
val rulify_term: Proof.context -> term -> term
val rulify_tac: Proof.context -> int -> tactic
val rulify: Proof.context -> thm -> thm
val rulify_no_asm: Proof.context -> thm -> thm
val rule_format: attribute
val rule_format_no_asm: attribute
end;
structure Object_Logic: OBJECT_LOGIC =
struct
(** context data **)
datatype data = Data of
{base_sort: sort option,
judgment: string option,
atomize_rulify: thm list * thm list};
fun make_data (base_sort, judgment, atomize_rulify) =
Data {base_sort = base_sort, judgment = judgment, atomize_rulify = atomize_rulify};
structure Data = Generic_Data
(
type T = data;
val empty = make_data (NONE, NONE, ([], []));
val extend = I;
fun merge_opt eq (SOME x, SOME y) =
if eq (x, y) then SOME x else error "Attempt to merge different object-logics"
| merge_opt _ data = merge_options data;
fun merge
(Data {base_sort = base_sort1, judgment = judgment1, atomize_rulify = (atomize1, rulify1)},
Data {base_sort = base_sort2, judgment = judgment2, atomize_rulify = (atomize2, rulify2)}) =
make_data (merge_opt (op =) (base_sort1, base_sort2), merge_opt (op =) (judgment1, judgment2),
(Thm.merge_thms (atomize1, atomize2), Thm.merge_thms (rulify1, rulify2)));
);
fun map_data f = Data.map (fn (Data {base_sort, judgment, atomize_rulify}) =>
make_data (f (base_sort, judgment, atomize_rulify)));
fun get_data ctxt = Data.get (Context.Proof ctxt) |> (fn Data args => args);
(** generic treatment of judgments -- with a single argument only **)
(* base_sort *)
val get_base_sort = #base_sort o get_data;
fun add_base_sort S =
(Context.theory_map o map_data) (fn (base_sort, judgment, atomize_rulify) =>
if is_some base_sort then error "Attempt to redeclare object-logic base sort"
else (SOME S, judgment, atomize_rulify));
(* add judgment *)
local
fun gen_add_judgment add_consts (b, T, mx) thy =
let
val c = Sign.full_name thy b;
val thy' = thy |> add_consts [(b, T, mx)];
val T' = Logic.unvarifyT_global (Sign.the_const_type thy' c);
in
thy'
|> Theory.add_deps_global "" (Theory.const_dep thy' (c, T')) []
|> (Context.theory_map o map_data) (fn (base_sort, judgment, atomize_rulify) =>
if is_some judgment then error "Attempt to redeclare object-logic judgment"
else (base_sort, SOME c, atomize_rulify))
end;
in
val add_judgment = gen_add_judgment Sign.add_consts;
val add_judgment_cmd = gen_add_judgment Sign.add_consts_cmd;
end;
(* judgments *)
fun judgment_name ctxt =
(case #judgment (get_data ctxt) of
SOME name => name
| _ => raise TERM ("Unknown object-logic judgment", []));
fun is_judgment ctxt (Const (c, _) $ _) = c = judgment_name ctxt
| is_judgment _ _ = false;
fun drop_judgment ctxt (Abs (x, T, t)) = Abs (x, T, drop_judgment ctxt t)
| drop_judgment ctxt (tm as (Const (c, _) $ t)) =
if (c = judgment_name ctxt handle TERM _ => false) then t else tm
| drop_judgment _ tm = tm;
fun fixed_judgment ctxt x =
let (*be robust wrt. low-level errors*)
val c = judgment_name ctxt;
val aT = Term.aT [];
val T =
the_default (aT --> propT) (Sign.const_type (Proof_Context.theory_of ctxt) c)
|> Term.map_type_tvar (fn ((a, _), S) => TFree (a, S));
val U = Term.domain_type T handle Match => aT;
in Const (c, T) $ Free (x, U) end;
fun ensure_propT ctxt t =
let val T = Term.fastype_of t
in if T = propT then t else Const (judgment_name ctxt, T --> propT) $ t end;
fun dest_judgment ctxt ct =
if is_judgment ctxt (Thm.term_of ct)
then Thm.dest_arg ct
else raise CTERM ("dest_judgment", [ct]);
fun judgment_conv ctxt cv ct =
if is_judgment ctxt (Thm.term_of ct)
then Conv.arg_conv cv ct
else raise CTERM ("judgment_conv", [ct]);
fun is_propositional ctxt T =
T = propT orelse
let val x = Free (singleton (Variable.variant_frees ctxt []) ("x", T))
in can (fn () => Syntax.check_term ctxt (ensure_propT ctxt x)) () end;
(* elimination rules *)
fun elim_concl ctxt rule =
let
val concl = Thm.concl_of rule;
val C = drop_judgment ctxt concl;
in
if Term.is_Var C andalso
exists (fn prem => concl aconv Logic.strip_assums_concl prem) (Thm.prems_of rule)
then SOME C else NONE
end;
(** treatment of meta-level connectives **)
(* maintain rules *)
fun get_atomize_rulify f ctxt = map (Thm.transfer' ctxt) (f (#atomize_rulify (get_data ctxt)));
val get_atomize = get_atomize_rulify #1;
val get_rulify = get_atomize_rulify #2;
fun add_atomize th = map_data (fn (base_sort, judgment, (atomize, rulify)) =>
(base_sort, judgment, (Thm.add_thm (Thm.trim_context th) atomize, rulify)));
fun add_rulify th = map_data (fn (base_sort, judgment, (atomize, rulify)) =>
(base_sort, judgment, (atomize, Thm.add_thm (Thm.trim_context th) rulify)));
val declare_atomize = Thm.declaration_attribute add_atomize;
val declare_rulify = Thm.declaration_attribute add_rulify;
val _ = Theory.setup (fold (Context.theory_map o add_rulify) Drule.norm_hhf_eqs);
(* atomize *)
fun atomize_term ctxt =
drop_judgment ctxt o
Raw_Simplifier.rewrite_term (Proof_Context.theory_of ctxt) (get_atomize ctxt) [];
fun atomize ctxt = Raw_Simplifier.rewrite ctxt true (get_atomize ctxt);
fun atomize_prems ctxt ct =
if Logic.has_meta_prems (Thm.term_of ct) then
Conv.params_conv ~1 (Conv.prems_conv ~1 o atomize) ctxt ct
else Conv.all_conv ct;
val atomize_prems_tac = CONVERSION o atomize_prems;
val full_atomize_tac = CONVERSION o atomize;
(* rulify *)
fun rulify_term ctxt =
Raw_Simplifier.rewrite_term (Proof_Context.theory_of ctxt) (get_rulify ctxt) [];
fun rulify_tac ctxt = rewrite_goal_tac ctxt (get_rulify ctxt);
fun gen_rulify full ctxt =
Conv.fconv_rule (Raw_Simplifier.rewrite ctxt full (get_rulify ctxt))
#> Variable.gen_all ctxt
#> Thm.strip_shyps
#> Drule.zero_var_indexes;
val rulify = gen_rulify true;
val rulify_no_asm = gen_rulify false;
val rule_format = Thm.rule_attribute [] (rulify o Context.proof_of);
val rule_format_no_asm = Thm.rule_attribute [] (rulify_no_asm o Context.proof_of);
end;