src/Pure/Proof/proofchecker.ML

--- a/src/Pure/Proof/proofchecker.ML	Mon Aug 08 16:47:55 2011 +0200
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,141 +0,0 @@
-(*  Title:      Pure/Proof/proofchecker.ML
-    Author:     Stefan Berghofer, TU Muenchen
-
-Simple proof checker based only on the core inference rules
-of Isabelle/Pure.
-*)
-
-signature PROOF_CHECKER =
-sig
-  val thm_of_proof : theory -> Proofterm.proof -> thm
-end;
-
-structure ProofChecker : PROOF_CHECKER =
-struct
-
-(***** construct a theorem out of a proof term *****)
-
-fun lookup_thm thy =
-  let val tab = fold_rev Symtab.update (Global_Theory.all_thms_of thy) Symtab.empty
-  in
-    (fn s => case Symtab.lookup tab s of
-       NONE => error ("Unknown theorem " ^ quote s)
-     | SOME thm => thm)
-  end;
-
-val beta_eta_convert =
-  Conv.fconv_rule Drule.beta_eta_conversion;
-
-(* equality modulo renaming of type variables *)
-fun is_equal t t' =
-  let
-    val atoms = fold_types (fold_atyps (insert (op =))) t [];
-    val atoms' = fold_types (fold_atyps (insert (op =))) t' []
-  in
-    length atoms = length atoms' andalso
-    map_types (map_atyps (the o AList.lookup (op =) (atoms ~~ atoms'))) t aconv t'
-  end;
-
-fun pretty_prf thy vs Hs prf =
-  let val prf' = prf |> Proofterm.prf_subst_bounds (map Free vs) |>
-    Proofterm.prf_subst_pbounds (map (Hyp o prop_of) Hs)
-  in
-    (Proof_Syntax.pretty_proof (Syntax.init_pretty_global thy) prf',
-     Syntax.pretty_term_global thy (Reconstruct.prop_of prf'))
-  end;
-
-fun pretty_term thy vs _ t =
-  let val t' = subst_bounds (map Free vs, t)
-  in
-    (Syntax.pretty_term_global thy t',
-     Syntax.pretty_typ_global thy (fastype_of t'))
-  end;
-
-fun appl_error thy prt vs Hs s f a =
-  let
-    val (pp_f, pp_fT) = pretty_prf thy vs Hs f;
-    val (pp_a, pp_aT) = prt thy vs Hs a
-  in
-    error (cat_lines
-      [s,
-       "",
-       Pretty.string_of (Pretty.block
-         [Pretty.str "Operator:", Pretty.brk 2, pp_f,
-           Pretty.str " ::", Pretty.brk 1, pp_fT]),
-       Pretty.string_of (Pretty.block
-         [Pretty.str "Operand:", Pretty.brk 3, pp_a,
-           Pretty.str " ::", Pretty.brk 1, pp_aT]),
-       ""])
-  end;
-
-fun thm_of_proof thy prf =
-  let
-    val prf_names = Proofterm.fold_proof_terms Term.declare_term_frees (K I) prf Name.context;
-    val lookup = lookup_thm thy;
-
-    fun thm_of_atom thm Ts =
-      let
-        val tvars = Term.add_tvars (Thm.full_prop_of thm) [] |> rev;
-        val (fmap, thm') = Thm.varifyT_global' [] thm;
-        val ctye = map (pairself (Thm.ctyp_of thy))
-          (map TVar tvars @ map (fn ((_, S), ixn) => TVar (ixn, S)) fmap ~~ Ts)
-      in
-        Thm.instantiate (ctye, []) (forall_intr_vars (Thm.forall_intr_frees thm'))
-      end;
-
-    fun thm_of _ _ (PThm (_, ((name, prop', SOME Ts), _))) =
-          let
-            val thm = Thm.unconstrainT (Drule.implies_intr_hyps (lookup name));
-            val {prop, ...} = rep_thm thm;
-            val _ = if is_equal prop prop' then () else
-              error ("Duplicate use of theorem name " ^ quote name ^ "\n" ^
-                Syntax.string_of_term_global thy prop ^ "\n\n" ^
-                Syntax.string_of_term_global thy prop');
-          in thm_of_atom thm Ts end
-
-      | thm_of _ _ (PAxm (name, _, SOME Ts)) =
-          thm_of_atom (Thm.axiom thy name) Ts
-
-      | thm_of _ Hs (PBound i) = nth Hs i
-
-      | thm_of (vs, names) Hs (Abst (s, SOME T, prf)) =
-          let
-            val (x, names') = Name.variant s names;
-            val thm = thm_of ((x, T) :: vs, names') Hs prf
-          in
-            Thm.forall_intr (Thm.cterm_of thy (Free (x, T))) thm
-          end
-
-      | thm_of (vs, names) Hs (prf % SOME t) =
-          let
-            val thm = thm_of (vs, names) Hs prf;
-            val ct = Thm.cterm_of thy (Term.subst_bounds (map Free vs, t));
-          in
-            Thm.forall_elim ct thm
-            handle THM (s, _, _) => appl_error thy pretty_term vs Hs s prf t
-          end
-
-      | thm_of (vs, names) Hs (AbsP (s, SOME t, prf)) =
-          let
-            val ct = Thm.cterm_of thy (Term.subst_bounds (map Free vs, t));
-            val thm = thm_of (vs, names) (Thm.assume ct :: Hs) prf;
-          in
-            Thm.implies_intr ct thm
-          end
-
-      | thm_of vars Hs (prf %% prf') =
-          let
-            val thm = beta_eta_convert (thm_of vars Hs prf);
-            val thm' = beta_eta_convert (thm_of vars Hs prf');
-          in
-            Thm.implies_elim thm thm'
-            handle THM (s, _, _) => appl_error thy pretty_prf (fst vars) Hs s prf prf'
-          end
-
-      | thm_of _ _ (Hyp t) = Thm.assume (Thm.cterm_of thy t)
-
-      | thm_of _ _ _ = error "thm_of_proof: partial proof term";
-
-  in beta_eta_convert (thm_of ([], prf_names) [] prf) end;
-
-end;