src/HOL/Tools/datatype_realizer.ML
author berghofe
Wed Nov 27 17:06:47 2002 +0100 (2002-11-27)
changeset 13725 12404b452034
parent 13708 a3a410782c95
child 14981 e73f8140af78
permissions -rw-r--r--
Changed format of realizers / correctness proofs.
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(*  Title:      HOL/Tools/datatype_realizer.ML
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    ID:         $Id$
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    Author:     Stefan Berghofer, TU Muenchen
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    License:    GPL (GNU GENERAL PUBLIC LICENSE)
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Porgram extraction from proofs involving datatypes:
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Realizers for induction and case analysis
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*)
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signature DATATYPE_REALIZER =
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sig
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  val add_dt_realizers: (string * sort) list ->
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    DatatypeAux.datatype_info list -> theory -> theory
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end;
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structure DatatypeRealizer : DATATYPE_REALIZER =
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struct
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open DatatypeAux;
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fun subsets i j = if i <= j then
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       let val is = subsets (i+1) j
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       in map (fn ks => i::ks) is @ is end
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     else [[]];
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fun forall_intr_prf (t, prf) =
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  let val (a, T) = (case t of Var ((a, _), T) => (a, T) | Free p => p)
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  in Abst (a, Some T, Proofterm.prf_abstract_over t prf) end;
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fun prf_of thm =
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  let val {sign, prop, der = (_, prf), ...} = rep_thm thm
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  in Reconstruct.reconstruct_proof sign prop prf end;
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fun prf_subst_vars inst =
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  Proofterm.map_proof_terms (subst_vars ([], inst)) I;
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fun is_unit t = snd (strip_type (fastype_of t)) = HOLogic.unitT;
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fun tname_of (Type (s, _)) = s
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  | tname_of _ = "";
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fun mk_realizes T = Const ("realizes", T --> HOLogic.boolT --> HOLogic.boolT);
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fun make_ind sorts ({descr, rec_names, rec_rewrites, induction, ...} : datatype_info) (is, thy) =
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  let
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    val sg = sign_of thy;
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    val recTs = get_rec_types descr sorts;
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    val pnames = if length descr = 1 then ["P"]
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      else map (fn i => "P" ^ string_of_int i) (1 upto length descr);
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    val rec_result_Ts = map (fn ((i, _), P) =>
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      if i mem is then TFree ("'" ^ P, HOLogic.typeS) else HOLogic.unitT)
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        (descr ~~ pnames);
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    fun make_pred i T U r x =
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      if i mem is then
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        Free (nth_elem (i, pnames), T --> U --> HOLogic.boolT) $ r $ x
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      else Free (nth_elem (i, pnames), U --> HOLogic.boolT) $ x;
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    fun mk_all i s T t =
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      if i mem is then list_all_free ([(s, T)], t) else t;
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    val (prems, rec_fns) = split_list (flat (snd (foldl_map
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      (fn (j, ((i, (_, _, constrs)), T)) => foldl_map (fn (j, (cname, cargs)) =>
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        let
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          val Ts = map (typ_of_dtyp descr sorts) cargs;
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          val tnames = variantlist (DatatypeProp.make_tnames Ts, pnames);
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          val recs = filter (is_rec_type o fst o fst) (cargs ~~ tnames ~~ Ts);
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          val frees = tnames ~~ Ts;
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          fun mk_prems vs [] = 
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                let
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                  val rT = nth_elem (i, rec_result_Ts);
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                  val vs' = filter_out is_unit vs;
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                  val f = mk_Free "f" (map fastype_of vs' ---> rT) j;
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                  val f' = Pattern.eta_contract (list_abs_free
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                    (map dest_Free vs, if i mem is then list_comb (f, vs')
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                      else HOLogic.unit));
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                in (HOLogic.mk_Trueprop (make_pred i rT T (list_comb (f, vs'))
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                  (list_comb (Const (cname, Ts ---> T), map Free frees))), f')
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                end
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            | mk_prems vs (((dt, s), T) :: ds) = 
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                let
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                  val k = body_index dt;
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                  val (Us, U) = strip_type T;
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                  val i = length Us;
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                  val rT = nth_elem (k, rec_result_Ts);
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                  val r = Free ("r" ^ s, Us ---> rT);
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                  val (p, f) = mk_prems (vs @ [r]) ds
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                in (mk_all k ("r" ^ s) (Us ---> rT) (Logic.mk_implies
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                  (list_all (map (pair "x") Us, HOLogic.mk_Trueprop
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                    (make_pred k rT U (app_bnds r i)
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                      (app_bnds (Free (s, T)) i))), p)), f)
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                end
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        in (j + 1,
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          apfst (curry list_all_free frees) (mk_prems (map Free frees) recs))
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        end) (j, constrs)) (1, descr ~~ recTs))));
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    fun mk_proj j [] t = t
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      | mk_proj j (i :: is) t = if null is then t else
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          if j = i then HOLogic.mk_fst t
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          else mk_proj j is (HOLogic.mk_snd t);
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    val tnames = DatatypeProp.make_tnames recTs;
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    val fTs = map fastype_of rec_fns;
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    val ps = map (fn ((((i, _), T), U), s) => Abs ("x", T, make_pred i U T
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      (list_comb (Const (s, fTs ---> T --> U), rec_fns) $ Bound 0) (Bound 0)))
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        (descr ~~ recTs ~~ rec_result_Ts ~~ rec_names);
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    val r = if null is then Extraction.nullt else
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      foldr1 HOLogic.mk_prod (mapfilter (fn (((((i, _), T), U), s), tname) =>
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        if i mem is then Some
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          (list_comb (Const (s, fTs ---> T --> U), rec_fns) $ Free (tname, T))
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        else None) (descr ~~ recTs ~~ rec_result_Ts ~~ rec_names ~~ tnames));
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    val concl = HOLogic.mk_Trueprop (foldr1 (HOLogic.mk_binop "op &")
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      (map (fn ((((i, _), T), U), tname) =>
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        make_pred i U T (mk_proj i is r) (Free (tname, T)))
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          (descr ~~ recTs ~~ rec_result_Ts ~~ tnames)));
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    val cert = cterm_of sg;
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    val inst = map (pairself cert) (map head_of (HOLogic.dest_conj
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      (HOLogic.dest_Trueprop (concl_of induction))) ~~ ps);
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    val thm = simple_prove_goal_cterm (cert (Logic.list_implies (prems, concl)))
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      (fn prems =>
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         [rewrite_goals_tac (map mk_meta_eq [fst_conv, snd_conv]),
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          rtac (cterm_instantiate inst induction) 1,
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          ALLGOALS ObjectLogic.atomize_tac,
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          rewrite_goals_tac (o_def :: map mk_meta_eq rec_rewrites),
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          REPEAT ((resolve_tac prems THEN_ALL_NEW (fn i =>
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            REPEAT (etac allE i) THEN atac i)) 1)]);
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    val {path, ...} = Sign.rep_sg sg;
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    val ind_name = Thm.name_of_thm induction;
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    val vs = map (fn i => nth_elem (i, pnames)) is;
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    val (thy', thm') = thy
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      |> Theory.absolute_path
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      |> PureThy.store_thm
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        ((space_implode "_" (ind_name :: vs @ ["correctness"]), thm), [])
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      |>> Theory.add_path (NameSpace.pack (if_none path []));
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    val ivs = Drule.vars_of_terms
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      [Logic.varify (DatatypeProp.make_ind [descr] sorts)];
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    val rvs = Drule.vars_of_terms [prop_of thm'];
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    val ivs1 = map Var (filter_out (fn (_, T) =>
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      tname_of (body_type T) mem ["set", "bool"]) ivs);
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    val ivs2 = map (fn (ixn, _) => Var (ixn, the (assoc (rvs, ixn)))) ivs;
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    val prf = foldr forall_intr_prf (ivs2,
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      foldr (fn ((f, p), prf) =>
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        (case head_of (strip_abs_body f) of
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           Free (s, T) =>
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             let val T' = Type.varifyT T
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             in Abst (s, Some T', Proofterm.prf_abstract_over
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               (Var ((s, 0), T')) (AbsP ("H", Some p, prf)))
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             end
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         | _ => AbsP ("H", Some p, prf)))
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           (rec_fns ~~ prems_of thm, Proofterm.proof_combP
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             (prf_of thm', map PBound (length prems - 1 downto 0))));
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    val r' = if null is then r else Logic.varify (foldr (uncurry lambda)
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      (map Logic.unvarify ivs1 @ filter_out is_unit
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        (map (head_of o strip_abs_body) rec_fns), r));
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  in Extraction.add_realizers_i [(ind_name, (vs, r', prf))] thy' end;
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fun make_casedists sorts ({index, descr, case_name, case_rewrites, exhaustion, ...} : datatype_info, thy) =
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  let
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    val sg = sign_of thy;
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    val sorts = map (rpair HOLogic.typeS) (distinct (flat (map
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      (fn (_, (_, ds, _)) => mapfilter (try dest_DtTFree) ds) descr)));
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    val cert = cterm_of sg;
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    val rT = TFree ("'P", HOLogic.typeS);
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    val rT' = TVar (("'P", 0), HOLogic.typeS);
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    fun make_casedist_prem T (cname, cargs) =
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      let
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        val Ts = map (typ_of_dtyp descr sorts) cargs;
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        val frees = variantlist
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          (DatatypeProp.make_tnames Ts, ["P", "y"]) ~~ Ts;
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        val free_ts = map Free frees;
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        val r = Free ("r" ^ NameSpace.base cname, Ts ---> rT)
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      in (r, list_all_free (frees, Logic.mk_implies (HOLogic.mk_Trueprop
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        (HOLogic.mk_eq (Free ("y", T), list_comb (Const (cname, Ts ---> T), free_ts))),
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          HOLogic.mk_Trueprop (Free ("P", rT --> HOLogic.boolT) $
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            list_comb (r, free_ts)))))
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      end;
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    val Some (_, _, constrs) = assoc (descr, index);
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    val T = nth_elem (index, get_rec_types descr sorts);
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    val (rs, prems) = split_list (map (make_casedist_prem T) constrs);
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    val r = Const (case_name, map fastype_of rs ---> T --> rT);
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    val y = Var (("y", 0), Type.varifyT T);
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    val y' = Free ("y", T);
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    val thm = prove_goalw_cterm [] (cert (Logic.list_implies (prems,
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      HOLogic.mk_Trueprop (Free ("P", rT --> HOLogic.boolT) $
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        list_comb (r, rs @ [y'])))))
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      (fn prems =>
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         [rtac (cterm_instantiate [(cert y, cert y')] exhaustion) 1,
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          ALLGOALS (EVERY'
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            [asm_simp_tac (HOL_basic_ss addsimps case_rewrites),
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             resolve_tac prems, asm_simp_tac HOL_basic_ss])]);
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    val {path, ...} = Sign.rep_sg sg;
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    val exh_name = Thm.name_of_thm exhaustion;
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    val (thy', thm') = thy
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      |> Theory.absolute_path
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      |> PureThy.store_thm ((exh_name ^ "_P_correctness", thm), [])
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      |>> Theory.add_path (NameSpace.pack (if_none path []));
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    val P = Var (("P", 0), rT' --> HOLogic.boolT);
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    val prf = forall_intr_prf (y, forall_intr_prf (P,
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      foldr (fn ((p, r), prf) =>
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        forall_intr_prf (Logic.varify r, AbsP ("H", Some (Logic.varify p),
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          prf))) (prems ~~ rs, Proofterm.proof_combP (prf_of thm',
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            map PBound (length prems - 1 downto 0)))));
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    val r' = Logic.varify (Abs ("y", Type.varifyT T,
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      list_abs (map dest_Free rs, list_comb (r,
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        map Bound ((length rs - 1 downto 0) @ [length rs])))));
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  in Extraction.add_realizers_i
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    [(exh_name, (["P"], r', prf)),
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     (exh_name, ([], Extraction.nullt, prf_of exhaustion))] thy'
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  end;
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fun add_dt_realizers sorts infos thy = if !proofs < 2 then thy else
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  (message "Adding realizers for induction and case analysis ..."; thy
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   |> curry (foldr (make_ind sorts (hd infos)))
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     (subsets 0 (length (#descr (hd infos)) - 1))
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   |> curry (foldr (make_casedists sorts)) infos);
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end;