- (* check: assuming we have more than one right parameter *)
- (* pred := P yr- *)
- let pred = mk_appl ((mk_id "P")::id_ys) in
-
- let selection = match selection with
- None -> HExtlib.mk_list true (List.length ys)
- | Some s -> s
- in
- let prods = mk_arrows id_rs id_ys selection pred in
-
- let lambdas = mk_lambdas (ys@["p"]) prods in
-
- let hyplist =
- let rec hypaux k = function
- 0 -> []
- | n -> ("H" ^ string_of_int k) :: hypaux (k+1) (n-1)
- in (hypaux 1 ncons)
- in
- prerr_endline ("lunghezza ys = " ^ string_of_int (List.length ys));
-
- let outsort, suffix = NCicElim.ast_of_sort outsort in
- let theorem = mk_prods xs
- (CicNotationPt.Binder (`Forall, (mk_id "P", Some (mk_prods (HExtlib.mk_list "_" (List.length ys)) (CicNotationPt.Sort outsort))),
- mk_prods hyplist (CicNotationPt.Binder (`Forall, (mk_id "Hterm", (*Some (mk_appl (List.map mk_id (ind_name::xs)))) *)
- Some (CicNotationPt.Implicit `JustOne)),
- mk_appl (mk_id "P"::id_rs)))))
- in
- let t = mk_appl ( [mk_id (ind_name ^ "_" ^ suffix); lambdas] @
- List.map mk_id hyplist @
- CicNotationPt.Implicit `Vector::[mk_id "Hterm"] ) in
-
- let status, theorem = GrafiteDisambiguate.disambiguate_nobj status ~baseuri
- (baseuri ^ name ^ ".def",
- 0,CicNotationPt.Theorem (`Theorem,name,theorem,Some (CicNotationPt.Implicit (`Tagged "inv")))) in
- let uri,height,nmenv,nsubst,nobj = theorem in
- let ninitial_stack = Continuationals.Stack.of_nmetasenv nmenv in
- let status = status#set_obj theorem in
- let status = status#set_stack ninitial_stack in
- let status = subst_metasenv_and_fix_names status in
-
- let cut_theorem =
- let rs = List.map (fun x -> mk_id x) rs in
- mk_arrows rs rs selection (mk_appl (mk_id "P"::rs)) in
-
- let cut = mk_appl [CicNotationPt.Binder (`Lambda, (mk_id "Hcut", Some cut_theorem),
- CicNotationPt.Implicit (`Tagged "end"));
- CicNotationPt.Implicit (`Tagged "cut")] in
-
- let intros = List.map (fun x -> NTactics.intro_tac x) (xs@["P"]@hyplist@["Hterm"]) in
-
- let status = NTactics.block_tac
- (NTactics.branch_tac::
- NTactics.case_tac "inv"::
- (intros @
- [NTactics.apply_tac ("",0,cut);
- NTactics.branch_tac;
- NTactics.case_tac "end";
- NTactics.apply_tac ("",0,mk_id "Hcut");
- NTactics.apply_tac ("",0,mk_id "refl_eq");
- NTactics.shift_tac;
- NTactics.case_tac "cut";
- NTactics.apply_tac ("",0,t);
- NTactics.merge_tac;
- NTactics.merge_tac;
- NTactics.skip_tac])) status in
- status,status#obj
+ pp (lazy ("nparams = " ^ string_of_int nparams));
+ if nparams = 0
+ then raise (Failure "inverter: the type must have at least one right parameter")
+ else
+ let xs = List.map (fun n -> "x" ^ (string_of_int n)) (HExtlib.list_seq 1 (leftno+nparams+1)) in
+ pp (lazy ("lunghezza xs = " ^ string_of_int (List.length xs)));
+ let ls, rs = HExtlib.split_nth leftno xs in
+ pp (lazy ("lunghezza ls = " ^ string_of_int (List.length ls)));
+ pp (lazy ("lunghezza rs = " ^ string_of_int (List.length rs)));
+ let ys = List.map (fun n -> "y" ^ (string_of_int n)) (HExtlib.list_seq (leftno+1) (leftno+nparams+1)) in
+
+ let _id_xs = List.map mk_id xs in
+ let id_ls = List.map mk_id ls in
+ let id_rs = List.map mk_id rs in
+ let id_ys = List.map mk_id ys in
+
+ (* pseudocode let t = Lambda y1 ... yr. xs_ = ys_ -> pred *)
+
+ (* check: assuming we have more than one right parameter *)
+ (* pred := P yr- *)
+ let pred = mk_appl ((mk_id "P")::id_ys) in
+
+ let selection = match selection with
+ None -> HExtlib.mk_list true (List.length ys)
+ | Some s -> s
+ in
+ let prods = mk_arrows id_rs id_ys selection pred in
+
+ let hyplist =
+ let rec hypaux k = function
+ 0 -> []
+ | n -> ("H" ^ string_of_int k) :: hypaux (k+1) (n-1)
+ in (hypaux 1 ncons)
+ in
+ pp (lazy ("lunghezza ys = " ^ string_of_int (List.length ys)));
+
+ let outsort, suffix = NCicElim.ast_of_sort outsort in
+ let theorem =
+ mk_prods xs
+ (CicNotationPt.Binder (`Forall, (mk_id "P", Some (mk_prods (HExtlib.mk_list "_" (List.length ys)) (CicNotationPt.Sort outsort))),
+ mk_prods hyplist (CicNotationPt.Binder (`Forall, (mk_id "Hterm", Some (mk_appl (List.map mk_id (ind_name::xs)))), mk_appl (mk_id "P"::id_rs)))))
+ in
+ let status, theorem =
+ GrafiteDisambiguate.disambiguate_nobj status ~baseuri
+ (baseuri ^ name ^ ".def",0,
+ CicNotationPt.Theorem
+ (`Theorem,name,theorem,
+ Some (CicNotationPt.Implicit (`Tagged "inv")),`InversionPrinciple))
+ in
+ let uri,height,nmenv,nsubst,nobj = theorem in
+ let ninitial_stack = Continuationals.Stack.of_nmetasenv nmenv in
+ let status = status#set_obj theorem in
+ let status = status#set_stack ninitial_stack in
+ let status = subst_metasenv_and_fix_names status in
+
+ let cut_theorem =
+ let rs = List.map (fun x -> mk_id x) rs in
+ mk_arrows rs rs selection (mk_appl (mk_id "P"::rs)) in
+
+ let cut = mk_appl [CicNotationPt.Binder (`Lambda, (mk_id "Hcut", Some cut_theorem),
+
+CicNotationPt.Implicit (`Tagged "end"));
+ CicNotationPt.Implicit (`Tagged "cut")] in
+ let intros = List.map (fun x -> pp (lazy x); NTactics.intro_tac x) (xs@["P"]@hyplist@["Hterm"]) in
+ let where =
+ "",0,(None,[],
+ Some (
+ mk_arrows ~pattern:true
+ (HExtlib.mk_list (CicNotationPt.Implicit `JustOne) (List.length ys))
+ (HExtlib.mk_list CicNotationPt.UserInput (List.length ys))
+ selection CicNotationPt.UserInput)) in
+ let elim_tac = if is_ind then NTactics.elim_tac else NTactics.cases_tac in
+ let status =
+ NTactics.block_tac
+ (NTactics.branch_tac ::
+ NTactics.case_tac "inv" ::
+ (intros @
+ [NTactics.apply_tac ("",0,cut);
+ NTactics.branch_tac;
+ NTactics.case_tac "end";
+ NTactics.apply_tac ("",0,mk_id "Hcut");
+ NTactics.apply_tac ("",0,mk_id "refl");
+ NTactics.shift_tac;
+ elim_tac ~what:("",0,mk_id "Hterm") ~where;
+ NTactics.branch_tac ~force:true] @
+ HExtlib.list_concat ~sep:[NTactics.shift_tac]
+ (List.map (fun id-> [NTactics.apply_tac ("",0,mk_id id)]) hyplist) @
+ [NTactics.merge_tac;
+ NTactics.merge_tac;
+ NTactics.merge_tac;
+ NTactics.skip_tac])) status in
+ pp (lazy "inv 3");
+ status,status#obj