TSTP Solution File: KRS116+1 by Zenon---0.7.1

View Problem - Process Solution 
%------------------------------------------------------------------------------
% File     : Zenon---0.7.1
% Problem  : KRS116+1 : TPTP v8.1.0. Released v3.1.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : run_zenon %s %d

% Computer : n023.cluster.edu
% Model    : x86_64 x86_64
% CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 2.10GHz
% Memory   : 8042.1875MB
% OS       : Linux 3.10.0-693.el7.x86_64
% CPULimit : 300s
% WCLimit  : 600s
% DateTime : Sun Jul 17 03:39:30 EDT 2022

% Result   : Unsatisfiable 2.78s 2.99s
% Output   : Proof 2.78s
% Verified : 
% SZS Type : -

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.07/0.12  % Problem  : KRS116+1 : TPTP v8.1.0. Released v3.1.0.
% 0.07/0.13  % Command  : run_zenon %s %d
% 0.13/0.34  % Computer : n023.cluster.edu
% 0.13/0.34  % Model    : x86_64 x86_64
% 0.13/0.34  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.13/0.34  % Memory   : 8042.1875MB
% 0.13/0.34  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.13/0.34  % CPULimit : 300
% 0.13/0.34  % WCLimit  : 600
% 0.13/0.34  % DateTime : Tue Jun  7 18:01:38 EDT 2022
% 0.13/0.34  % CPUTime  : 
% 2.78/2.99  (* PROOF-FOUND *)
% 2.78/2.99  % SZS status Unsatisfiable
% 2.78/2.99  (* BEGIN-PROOF *)
% 2.78/2.99  % SZS output start Proof
% 2.78/2.99  Theorem zenon_thm : False.
% 2.78/2.99  Proof.
% 2.78/2.99  assert (zenon_L1_ : forall (zenon_TY_w : zenon_U) (zenon_TY_x : zenon_U) (zenon_TY_y : zenon_U), (rp zenon_TY_y zenon_TY_x) -> (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (~(rp zenon_TY_y zenon_TY_w)) -> (rp zenon_TY_x zenon_TY_w) -> False).
% 2.78/2.99  do 3 intro. intros zenon_H12 zenon_H13 zenon_H14 zenon_H15.
% 2.78/2.99  elim (classic ((~(zenon_TY_y = zenon_TY_x))/\(~(rp zenon_TY_y zenon_TY_x)))); [ zenon_intro zenon_H19 | zenon_intro zenon_H1a ].
% 2.78/2.99  apply (zenon_and_s _ _ zenon_H19). zenon_intro zenon_H1c. zenon_intro zenon_H1b.
% 2.78/2.99  exact (zenon_H1b zenon_H12).
% 2.78/2.99  cut ((rp zenon_TY_x zenon_TY_w) = (rp zenon_TY_y zenon_TY_w)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H14.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H15.
% 2.78/2.99  cut ((zenon_TY_w = zenon_TY_w)); [idtac | apply NNPP; zenon_intro zenon_H1d].
% 2.78/2.99  cut ((zenon_TY_x = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H1e].
% 2.78/2.99  congruence.
% 2.78/2.99  apply (zenon_notand_s _ _ zenon_H1a); [ zenon_intro zenon_H20 | zenon_intro zenon_H1f ].
% 2.78/2.99  apply zenon_H20. zenon_intro zenon_H21.
% 2.78/2.99  elim (classic (zenon_TY_y = zenon_TY_y)); [ zenon_intro zenon_H22 | zenon_intro zenon_H23 ].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y) = (zenon_TY_x = zenon_TY_y)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H1e.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H22.
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H23].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_x)); [idtac | apply NNPP; zenon_intro zenon_H1c].
% 2.78/2.99  congruence.
% 2.78/2.99  exact (zenon_H1c zenon_H21).
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H1f. zenon_intro zenon_H12.
% 2.78/2.99  generalize (zenon_H13 zenon_TY_y). zenon_intro zenon_H24.
% 2.78/2.99  generalize (zenon_H24 zenon_TY_x). zenon_intro zenon_H25.
% 2.78/2.99  generalize (zenon_H25 zenon_TY_w). zenon_intro zenon_H26.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H26); [ zenon_intro zenon_H1b | zenon_intro zenon_H27 ].
% 2.78/2.99  exact (zenon_H1b zenon_H12).
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H27); [ zenon_intro zenon_H29 | zenon_intro zenon_H28 ].
% 2.78/2.99  exact (zenon_H29 zenon_H15).
% 2.78/2.99  exact (zenon_H14 zenon_H28).
% 2.78/2.99  apply zenon_H1d. apply refl_equal.
% 2.78/2.99  (* end of lemma zenon_L1_ *)
% 2.78/2.99  assert (zenon_L2_ : forall (zenon_TY_bs : zenon_U) (zenon_TY_w : zenon_U) (zenon_TY_x : zenon_U) (zenon_TY_y : zenon_U), (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_x zenon_TY_w) -> (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (~(rp zenon_TY_y zenon_TY_bs)) -> (rp zenon_TY_w zenon_TY_bs) -> False).
% 2.78/2.99  do 4 intro. intros zenon_H12 zenon_H15 zenon_H13 zenon_H2a zenon_H2b.
% 2.78/2.99  elim (classic ((~(zenon_TY_y = zenon_TY_w))/\(~(rp zenon_TY_y zenon_TY_w)))); [ zenon_intro zenon_H2d | zenon_intro zenon_H2e ].
% 2.78/2.99  apply (zenon_and_s _ _ zenon_H2d). zenon_intro zenon_H2f. zenon_intro zenon_H14.
% 2.78/2.99  apply (zenon_L1_ zenon_TY_w zenon_TY_x zenon_TY_y); trivial.
% 2.78/2.99  cut ((rp zenon_TY_w zenon_TY_bs) = (rp zenon_TY_y zenon_TY_bs)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H2a.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H2b.
% 2.78/2.99  cut ((zenon_TY_bs = zenon_TY_bs)); [idtac | apply NNPP; zenon_intro zenon_H30].
% 2.78/2.99  cut ((zenon_TY_w = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H31].
% 2.78/2.99  congruence.
% 2.78/2.99  apply (zenon_notand_s _ _ zenon_H2e); [ zenon_intro zenon_H33 | zenon_intro zenon_H32 ].
% 2.78/2.99  apply zenon_H33. zenon_intro zenon_H34.
% 2.78/2.99  elim (classic (zenon_TY_y = zenon_TY_y)); [ zenon_intro zenon_H22 | zenon_intro zenon_H23 ].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y) = (zenon_TY_w = zenon_TY_y)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H31.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H22.
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H23].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_w)); [idtac | apply NNPP; zenon_intro zenon_H2f].
% 2.78/2.99  congruence.
% 2.78/2.99  exact (zenon_H2f zenon_H34).
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H32. zenon_intro zenon_H28.
% 2.78/2.99  generalize (zenon_H13 zenon_TY_y). zenon_intro zenon_H24.
% 2.78/2.99  generalize (zenon_H24 zenon_TY_w). zenon_intro zenon_H35.
% 2.78/2.99  generalize (zenon_H35 zenon_TY_bs). zenon_intro zenon_H36.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H36); [ zenon_intro zenon_H14 | zenon_intro zenon_H37 ].
% 2.78/2.99  exact (zenon_H14 zenon_H28).
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H37); [ zenon_intro zenon_H39 | zenon_intro zenon_H38 ].
% 2.78/2.99  exact (zenon_H39 zenon_H2b).
% 2.78/2.99  exact (zenon_H2a zenon_H38).
% 2.78/2.99  apply zenon_H30. apply refl_equal.
% 2.78/2.99  (* end of lemma zenon_L2_ *)
% 2.78/2.99  assert (zenon_L3_ : forall (zenon_TY_ci : zenon_U) (zenon_TY_bs : zenon_U) (zenon_TY_y : zenon_U) (zenon_TY_w : zenon_U) (zenon_TY_x : zenon_U), (rp zenon_TY_x zenon_TY_w) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_w zenon_TY_bs) -> (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (~(rp zenon_TY_y zenon_TY_ci)) -> (rp zenon_TY_bs zenon_TY_ci) -> False).
% 2.78/2.99  do 5 intro. intros zenon_H15 zenon_H12 zenon_H2b zenon_H13 zenon_H3a zenon_H3b.
% 2.78/2.99  elim (classic ((~(zenon_TY_y = zenon_TY_bs))/\(~(rp zenon_TY_y zenon_TY_bs)))); [ zenon_intro zenon_H3d | zenon_intro zenon_H3e ].
% 2.78/2.99  apply (zenon_and_s _ _ zenon_H3d). zenon_intro zenon_H3f. zenon_intro zenon_H2a.
% 2.78/2.99  apply (zenon_L2_ zenon_TY_bs zenon_TY_w zenon_TY_x zenon_TY_y); trivial.
% 2.78/2.99  cut ((rp zenon_TY_bs zenon_TY_ci) = (rp zenon_TY_y zenon_TY_ci)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H3a.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H3b.
% 2.78/2.99  cut ((zenon_TY_ci = zenon_TY_ci)); [idtac | apply NNPP; zenon_intro zenon_H40].
% 2.78/2.99  cut ((zenon_TY_bs = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H41].
% 2.78/2.99  congruence.
% 2.78/2.99  apply (zenon_notand_s _ _ zenon_H3e); [ zenon_intro zenon_H43 | zenon_intro zenon_H42 ].
% 2.78/2.99  apply zenon_H43. zenon_intro zenon_H44.
% 2.78/2.99  elim (classic (zenon_TY_y = zenon_TY_y)); [ zenon_intro zenon_H22 | zenon_intro zenon_H23 ].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y) = (zenon_TY_bs = zenon_TY_y)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H41.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H22.
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H23].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_bs)); [idtac | apply NNPP; zenon_intro zenon_H3f].
% 2.78/2.99  congruence.
% 2.78/2.99  exact (zenon_H3f zenon_H44).
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H42. zenon_intro zenon_H38.
% 2.78/2.99  generalize (zenon_H13 zenon_TY_y). zenon_intro zenon_H24.
% 2.78/2.99  generalize (zenon_H24 zenon_TY_bs). zenon_intro zenon_H45.
% 2.78/2.99  generalize (zenon_H45 zenon_TY_ci). zenon_intro zenon_H46.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H46); [ zenon_intro zenon_H2a | zenon_intro zenon_H47 ].
% 2.78/2.99  exact (zenon_H2a zenon_H38).
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H47); [ zenon_intro zenon_H49 | zenon_intro zenon_H48 ].
% 2.78/2.99  exact (zenon_H49 zenon_H3b).
% 2.78/2.99  exact (zenon_H3a zenon_H48).
% 2.78/2.99  apply zenon_H40. apply refl_equal.
% 2.78/2.99  (* end of lemma zenon_L3_ *)
% 2.78/2.99  assert (zenon_L4_ : forall (zenon_TY_cy : zenon_U) (zenon_TY_ci : zenon_U) (zenon_TY_x : zenon_U) (zenon_TY_y : zenon_U) (zenon_TY_bs : zenon_U) (zenon_TY_w : zenon_U), (rp zenon_TY_w zenon_TY_bs) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_x zenon_TY_w) -> (rp zenon_TY_bs zenon_TY_ci) -> (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (~(rp zenon_TY_y zenon_TY_cy)) -> (rp zenon_TY_ci zenon_TY_cy) -> False).
% 2.78/2.99  do 6 intro. intros zenon_H2b zenon_H12 zenon_H15 zenon_H3b zenon_H13 zenon_H4a zenon_H4b.
% 2.78/2.99  elim (classic ((~(zenon_TY_y = zenon_TY_ci))/\(~(rp zenon_TY_y zenon_TY_ci)))); [ zenon_intro zenon_H4d | zenon_intro zenon_H4e ].
% 2.78/2.99  apply (zenon_and_s _ _ zenon_H4d). zenon_intro zenon_H4f. zenon_intro zenon_H3a.
% 2.78/2.99  apply (zenon_L3_ zenon_TY_ci zenon_TY_bs zenon_TY_y zenon_TY_w zenon_TY_x); trivial.
% 2.78/2.99  cut ((rp zenon_TY_ci zenon_TY_cy) = (rp zenon_TY_y zenon_TY_cy)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H4a.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H4b.
% 2.78/2.99  cut ((zenon_TY_cy = zenon_TY_cy)); [idtac | apply NNPP; zenon_intro zenon_H50].
% 2.78/2.99  cut ((zenon_TY_ci = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H51].
% 2.78/2.99  congruence.
% 2.78/2.99  apply (zenon_notand_s _ _ zenon_H4e); [ zenon_intro zenon_H53 | zenon_intro zenon_H52 ].
% 2.78/2.99  apply zenon_H53. zenon_intro zenon_H54.
% 2.78/2.99  elim (classic (zenon_TY_y = zenon_TY_y)); [ zenon_intro zenon_H22 | zenon_intro zenon_H23 ].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y) = (zenon_TY_ci = zenon_TY_y)).
% 2.78/2.99  intro zenon_D_pnotp.
% 2.78/2.99  apply zenon_H51.
% 2.78/2.99  rewrite <- zenon_D_pnotp.
% 2.78/2.99  exact zenon_H22.
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_y)); [idtac | apply NNPP; zenon_intro zenon_H23].
% 2.78/2.99  cut ((zenon_TY_y = zenon_TY_ci)); [idtac | apply NNPP; zenon_intro zenon_H4f].
% 2.78/2.99  congruence.
% 2.78/2.99  exact (zenon_H4f zenon_H54).
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H23. apply refl_equal.
% 2.78/2.99  apply zenon_H52. zenon_intro zenon_H48.
% 2.78/2.99  generalize (zenon_H13 zenon_TY_y). zenon_intro zenon_H24.
% 2.78/2.99  generalize (zenon_H24 zenon_TY_ci). zenon_intro zenon_H55.
% 2.78/2.99  generalize (zenon_H55 zenon_TY_cy). zenon_intro zenon_H56.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H56); [ zenon_intro zenon_H3a | zenon_intro zenon_H57 ].
% 2.78/2.99  exact (zenon_H3a zenon_H48).
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H57); [ zenon_intro zenon_H59 | zenon_intro zenon_H58 ].
% 2.78/2.99  exact (zenon_H59 zenon_H4b).
% 2.78/2.99  exact (zenon_H4a zenon_H58).
% 2.78/2.99  apply zenon_H50. apply refl_equal.
% 2.78/2.99  (* end of lemma zenon_L4_ *)
% 2.78/2.99  assert (zenon_L5_ : (caxcomp (i2003_11_14_17_21_33997)) -> False).
% 2.78/2.99  do 0 intro. intros zenon_H5a.
% 2.78/2.99  generalize (axiom_5 (i2003_11_14_17_21_33997)). zenon_intro zenon_H5b.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H5b); [ zenon_intro zenon_H5e; zenon_intro zenon_H5d | zenon_intro zenon_H5a; zenon_intro zenon_H5c ].
% 2.78/2.99  exact (zenon_H5e zenon_H5a).
% 2.78/2.99  generalize (axiom_2 (i2003_11_14_17_21_33997)). zenon_intro zenon_H5f.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H5f); [ zenon_intro zenon_H61 | zenon_intro zenon_H60 ].
% 2.78/2.99  exact (zenon_H61 axiom_17).
% 2.78/2.99  generalize (axiom_4 (i2003_11_14_17_21_33997)). zenon_intro zenon_H62.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H62); [ zenon_intro zenon_H64; zenon_intro zenon_H63 | zenon_intro zenon_H60; zenon_intro zenon_H5d ].
% 2.78/2.99  exact (zenon_H64 zenon_H60).
% 2.78/2.99  exact (zenon_H5d zenon_H5c).
% 2.78/2.99  (* end of lemma zenon_L5_ *)
% 2.78/2.99  assert (zenon_L6_ : forall (zenon_TY_y : zenon_U), (ca_Vx6 zenon_TY_y) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> False).
% 2.78/2.99  do 1 intro. intros zenon_H65 zenon_H66.
% 2.78/2.99  generalize (axiom_11 zenon_TY_y). zenon_intro zenon_H67.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H67); [ zenon_intro zenon_H6a; zenon_intro zenon_H69 | zenon_intro zenon_H65; zenon_intro zenon_H68 ].
% 2.78/2.99  exact (zenon_H6a zenon_H65).
% 2.78/2.99  generalize (zenon_H68 (i2003_11_14_17_21_33997)). zenon_intro zenon_H6b.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H6b); [ zenon_intro zenon_H6c | zenon_intro zenon_H5a ].
% 2.78/2.99  generalize (axiom_15 zenon_TY_y). zenon_intro zenon_H6d.
% 2.78/2.99  generalize (zenon_H6d (i2003_11_14_17_21_33997)). zenon_intro zenon_H6e.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H6e); [ zenon_intro zenon_H6c; zenon_intro zenon_H70 | zenon_intro zenon_H6f; zenon_intro zenon_H66 ].
% 2.78/2.99  exact (zenon_H70 zenon_H66).
% 2.78/2.99  exact (zenon_H6c zenon_H6f).
% 2.78/2.99  apply (zenon_L5_); trivial.
% 2.78/2.99  (* end of lemma zenon_L6_ *)
% 2.78/2.99  assert (zenon_L7_ : forall (zenon_TY_y : zenon_U) (zenon_TY_w : zenon_U) (zenon_TY_x : zenon_U) (zenon_TY_ci : zenon_U) (zenon_TY_bs : zenon_U) (zenon_TY_cy : zenon_U), (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (ca_Vx7 zenon_TY_cy) -> (rp zenon_TY_bs zenon_TY_ci) -> (rp zenon_TY_x zenon_TY_w) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_w zenon_TY_bs) -> (rp zenon_TY_ci zenon_TY_cy) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> False).
% 2.78/2.99  do 6 intro. intros zenon_H13 zenon_H71 zenon_H3b zenon_H15 zenon_H12 zenon_H2b zenon_H4b zenon_H66.
% 2.78/2.99  generalize (axiom_12 zenon_TY_cy). zenon_intro zenon_H72.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H72); [ zenon_intro zenon_H75; zenon_intro zenon_H74 | zenon_intro zenon_H71; zenon_intro zenon_H73 ].
% 2.78/2.99  exact (zenon_H75 zenon_H71).
% 2.78/2.99  generalize (zenon_H73 zenon_TY_y). zenon_intro zenon_H76.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H76); [ zenon_intro zenon_H77 | zenon_intro zenon_H65 ].
% 2.78/2.99  generalize (axiom_13 zenon_TY_cy). zenon_intro zenon_H78.
% 2.78/2.99  generalize (zenon_H78 zenon_TY_y). zenon_intro zenon_H79.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H79); [ zenon_intro zenon_H77; zenon_intro zenon_H4a | zenon_intro zenon_H7a; zenon_intro zenon_H58 ].
% 2.78/2.99  apply (zenon_L4_ zenon_TY_cy zenon_TY_ci zenon_TY_x zenon_TY_y zenon_TY_bs zenon_TY_w); trivial.
% 2.78/2.99  exact (zenon_H77 zenon_H7a).
% 2.78/2.99  apply (zenon_L6_ zenon_TY_y); trivial.
% 2.78/2.99  (* end of lemma zenon_L7_ *)
% 2.78/2.99  assert (zenon_L8_ : forall (zenon_TY_x : zenon_U) (zenon_TY_bs : zenon_U) (zenon_TY_w : zenon_U) (zenon_TY_ci : zenon_U) (zenon_TY_y : zenon_U) (zenon_TY_cy : zenon_U) (zenon_TY_ev : zenon_U), (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (cc zenon_TY_ev) -> (rr zenon_TY_cy zenon_TY_ev) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> (rp zenon_TY_ci zenon_TY_cy) -> (rp zenon_TY_w zenon_TY_bs) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_x zenon_TY_w) -> (rp zenon_TY_bs zenon_TY_ci) -> False).
% 2.78/2.99  do 7 intro. intros zenon_H13 zenon_H7b zenon_H7c zenon_H66 zenon_H4b zenon_H2b zenon_H12 zenon_H15 zenon_H3b.
% 2.78/2.99  generalize (axiom_6 zenon_TY_ev). zenon_intro zenon_H7e.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H7e); [ zenon_intro zenon_H81; zenon_intro zenon_H80 | zenon_intro zenon_H7b; zenon_intro zenon_H7f ].
% 2.78/2.99  exact (zenon_H81 zenon_H7b).
% 2.78/2.99  generalize (zenon_H7f zenon_TY_cy). zenon_intro zenon_H82.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H82); [ zenon_intro zenon_H83 | zenon_intro zenon_H71 ].
% 2.78/2.99  generalize (axiom_14 zenon_TY_ev). zenon_intro zenon_H84.
% 2.78/2.99  generalize (zenon_H84 zenon_TY_cy). zenon_intro zenon_H85.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H85); [ zenon_intro zenon_H83; zenon_intro zenon_H87 | zenon_intro zenon_H86; zenon_intro zenon_H7c ].
% 2.78/2.99  exact (zenon_H87 zenon_H7c).
% 2.78/2.99  exact (zenon_H83 zenon_H86).
% 2.78/2.99  apply (zenon_L7_ zenon_TY_y zenon_TY_w zenon_TY_x zenon_TY_ci zenon_TY_bs zenon_TY_cy); trivial.
% 2.78/2.99  (* end of lemma zenon_L8_ *)
% 2.78/2.99  assert (zenon_L9_ : forall (zenon_TY_x : zenon_U) (zenon_TY_bs : zenon_U) (zenon_TY_w : zenon_U) (zenon_TY_y : zenon_U) (zenon_TY_ci : zenon_U), (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (ca_Vx4 zenon_TY_ci) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx3 Y))) -> (rp zenon_TY_w zenon_TY_bs) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_x zenon_TY_w) -> (rp zenon_TY_bs zenon_TY_ci) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx5 Y))) -> False).
% 2.78/2.99  do 5 intro. intros zenon_H13 zenon_H88 zenon_H89 zenon_H2b zenon_H12 zenon_H15 zenon_H3b zenon_H66 zenon_H8a.
% 2.78/2.99  generalize (axiom_9 zenon_TY_ci). zenon_intro zenon_H8b.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H8b); [ zenon_intro zenon_H8e; zenon_intro zenon_H8d | zenon_intro zenon_H88; zenon_intro zenon_H8c ].
% 2.78/2.99  exact (zenon_H8e zenon_H88).
% 2.78/2.99  elim zenon_H8c. zenon_intro zenon_TY_cy. zenon_intro zenon_H8f.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_H8f). zenon_intro zenon_H4b. zenon_intro zenon_H90.
% 2.78/2.99  generalize (zenon_H89 zenon_TY_cy). zenon_intro zenon_H91.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H91); [ zenon_intro zenon_H4a | zenon_intro zenon_H92 ].
% 2.78/2.99  apply (zenon_L4_ zenon_TY_cy zenon_TY_ci zenon_TY_x zenon_TY_y zenon_TY_bs zenon_TY_w); trivial.
% 2.78/2.99  generalize (axiom_8 zenon_TY_cy). zenon_intro zenon_H93.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H93); [ zenon_intro zenon_H96; zenon_intro zenon_H95 | zenon_intro zenon_H92; zenon_intro zenon_H94 ].
% 2.78/2.99  exact (zenon_H96 zenon_H92).
% 2.78/2.99  elim zenon_H94. zenon_intro zenon_TY_ev. zenon_intro zenon_H97.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_H97). zenon_intro zenon_H7c. zenon_intro zenon_H98.
% 2.78/2.99  generalize (zenon_H8a zenon_TY_cy). zenon_intro zenon_H99.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H99); [ zenon_intro zenon_H4a | zenon_intro zenon_H9a ].
% 2.78/2.99  apply (zenon_L4_ zenon_TY_cy zenon_TY_ci zenon_TY_x zenon_TY_y zenon_TY_bs zenon_TY_w); trivial.
% 2.78/2.99  generalize (axiom_10 zenon_TY_cy). zenon_intro zenon_H9b.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_H9b); [ zenon_intro zenon_H9e; zenon_intro zenon_H9d | zenon_intro zenon_H9a; zenon_intro zenon_H9c ].
% 2.78/2.99  exact (zenon_H9e zenon_H9a).
% 2.78/2.99  generalize (zenon_H9c zenon_TY_ev). zenon_intro zenon_H9f.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_H9f); [ zenon_intro zenon_H87 | zenon_intro zenon_H7b ].
% 2.78/2.99  exact (zenon_H87 zenon_H7c).
% 2.78/2.99  apply (zenon_L8_ zenon_TY_x zenon_TY_bs zenon_TY_w zenon_TY_ci zenon_TY_y zenon_TY_cy zenon_TY_ev); trivial.
% 2.78/2.99  (* end of lemma zenon_L9_ *)
% 2.78/2.99  assert (zenon_L10_ : forall (zenon_TY_w : zenon_U) (zenon_TY_x : zenon_U) (zenon_TY_y : zenon_U) (zenon_TY_bs : zenon_U), (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (ca_Vx4 zenon_TY_bs) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx4 Y))) -> (rp zenon_TY_x zenon_TY_w) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_w zenon_TY_bs) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx5 Y))) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx3 Y))) -> False).
% 2.78/2.99  do 4 intro. intros zenon_H13 zenon_Ha0 zenon_Ha1 zenon_H15 zenon_H12 zenon_H2b zenon_H8a zenon_H66 zenon_H89.
% 2.78/2.99  generalize (axiom_9 zenon_TY_bs). zenon_intro zenon_Ha2.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_Ha2); [ zenon_intro zenon_Ha5; zenon_intro zenon_Ha4 | zenon_intro zenon_Ha0; zenon_intro zenon_Ha3 ].
% 2.78/2.99  exact (zenon_Ha5 zenon_Ha0).
% 2.78/2.99  elim zenon_Ha3. zenon_intro zenon_TY_ci. zenon_intro zenon_Ha6.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Ha6). zenon_intro zenon_H3b. zenon_intro zenon_Ha7.
% 2.78/2.99  generalize (zenon_Ha1 zenon_TY_ci). zenon_intro zenon_Ha8.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_Ha8); [ zenon_intro zenon_H3a | zenon_intro zenon_H88 ].
% 2.78/2.99  apply (zenon_L3_ zenon_TY_ci zenon_TY_bs zenon_TY_y zenon_TY_w zenon_TY_x); trivial.
% 2.78/2.99  apply (zenon_L9_ zenon_TY_x zenon_TY_bs zenon_TY_w zenon_TY_y zenon_TY_ci); trivial.
% 2.78/2.99  (* end of lemma zenon_L10_ *)
% 2.78/2.99  assert (zenon_L11_ : forall (zenon_TY_x : zenon_U) (zenon_TY_y : zenon_U) (zenon_TY_w : zenon_U), (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (ca_Vx4 zenon_TY_w) -> (rp zenon_TY_y zenon_TY_x) -> (rp zenon_TY_x zenon_TY_w) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx3 Y))) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx5 Y))) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx4 Y))) -> False).
% 2.78/2.99  do 3 intro. intros zenon_H13 zenon_Ha9 zenon_H12 zenon_H15 zenon_H89 zenon_H66 zenon_H8a zenon_Ha1.
% 2.78/2.99  generalize (axiom_9 zenon_TY_w). zenon_intro zenon_Haa.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_Haa); [ zenon_intro zenon_Had; zenon_intro zenon_Hac | zenon_intro zenon_Ha9; zenon_intro zenon_Hab ].
% 2.78/2.99  exact (zenon_Had zenon_Ha9).
% 2.78/2.99  elim zenon_Hab. zenon_intro zenon_TY_bs. zenon_intro zenon_Hae.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hae). zenon_intro zenon_H2b. zenon_intro zenon_Haf.
% 2.78/2.99  generalize (zenon_Ha1 zenon_TY_bs). zenon_intro zenon_Hb0.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_Hb0); [ zenon_intro zenon_H2a | zenon_intro zenon_Ha0 ].
% 2.78/2.99  apply (zenon_L2_ zenon_TY_bs zenon_TY_w zenon_TY_x zenon_TY_y); trivial.
% 2.78/2.99  apply (zenon_L10_ zenon_TY_w zenon_TY_x zenon_TY_y zenon_TY_bs); trivial.
% 2.78/2.99  (* end of lemma zenon_L11_ *)
% 2.78/2.99  assert (zenon_L12_ : forall (zenon_TY_y : zenon_U) (zenon_TY_x : zenon_U), (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z)))))) -> (ca_Vx4 zenon_TY_x) -> (rp zenon_TY_y zenon_TY_x) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx4 Y))) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx5 Y))) -> (rs (i2003_11_14_17_21_33997) zenon_TY_y) -> (forall Y : zenon_U, ((rp zenon_TY_y Y)->(ca_Vx3 Y))) -> False).
% 2.78/2.99  do 2 intro. intros zenon_H13 zenon_Hb1 zenon_H12 zenon_Ha1 zenon_H8a zenon_H66 zenon_H89.
% 2.78/2.99  generalize (axiom_9 zenon_TY_x). zenon_intro zenon_Hb2.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_Hb2); [ zenon_intro zenon_Hb5; zenon_intro zenon_Hb4 | zenon_intro zenon_Hb1; zenon_intro zenon_Hb3 ].
% 2.78/2.99  exact (zenon_Hb5 zenon_Hb1).
% 2.78/2.99  elim zenon_Hb3. zenon_intro zenon_TY_w. zenon_intro zenon_Hb6.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hb6). zenon_intro zenon_H15. zenon_intro zenon_Hb7.
% 2.78/2.99  generalize (zenon_Ha1 zenon_TY_w). zenon_intro zenon_Hb8.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_Hb8); [ zenon_intro zenon_H14 | zenon_intro zenon_Ha9 ].
% 2.78/2.99  apply (zenon_L1_ zenon_TY_w zenon_TY_x zenon_TY_y); trivial.
% 2.78/2.99  apply (zenon_L11_ zenon_TY_x zenon_TY_y zenon_TY_w); trivial.
% 2.78/2.99  (* end of lemma zenon_L12_ *)
% 2.78/2.99  elim (classic (forall x : zenon_U, (forall y : zenon_U, (forall z : zenon_U, ((rp x y)->((rp y z)->(rp x z))))))); [ zenon_intro zenon_H13 | zenon_intro zenon_Hb9 ].
% 2.78/2.99  generalize (axiom_3 (i2003_11_14_17_21_33997)). zenon_intro zenon_Hba.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_Hba); [ zenon_intro zenon_H61 | zenon_intro zenon_Hbb ].
% 2.78/2.99  exact (zenon_H61 axiom_17).
% 2.78/2.99  elim zenon_Hbb. zenon_intro zenon_TY_y. zenon_intro zenon_Hbc.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hbc). zenon_intro zenon_H66. zenon_intro zenon_Hbd.
% 2.78/2.99  generalize (axiom_7 zenon_TY_y). zenon_intro zenon_Hbe.
% 2.78/2.99  apply (zenon_equiv_s _ _ zenon_Hbe); [ zenon_intro zenon_Hc1; zenon_intro zenon_Hc0 | zenon_intro zenon_Hbd; zenon_intro zenon_Hbf ].
% 2.78/2.99  exact (zenon_Hc1 zenon_Hbd).
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hbf). zenon_intro zenon_H89. zenon_intro zenon_Hc2.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hc2). zenon_intro zenon_H8a. zenon_intro zenon_Hc3.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hc3). zenon_intro zenon_Hc5. zenon_intro zenon_Hc4.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hc4). zenon_intro zenon_Hc7. zenon_intro zenon_Hc6.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hc6). zenon_intro zenon_Hc8. zenon_intro zenon_Ha1.
% 2.78/2.99  elim zenon_Hc8. zenon_intro zenon_TY_x. zenon_intro zenon_Hc9.
% 2.78/2.99  apply (zenon_and_s _ _ zenon_Hc9). zenon_intro zenon_H12. zenon_intro zenon_Hca.
% 2.78/2.99  generalize (zenon_Ha1 zenon_TY_x). zenon_intro zenon_Hcb.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_Hcb); [ zenon_intro zenon_H1b | zenon_intro zenon_Hb1 ].
% 2.78/2.99  exact (zenon_H1b zenon_H12).
% 2.78/2.99  apply (zenon_L12_ zenon_TY_y zenon_TY_x); trivial.
% 2.78/2.99  apply zenon_Hb9. zenon_intro zenon_Tx_hw. apply NNPP. zenon_intro zenon_Hcd.
% 2.78/2.99  apply zenon_Hcd. zenon_intro zenon_Ty_hy. apply NNPP. zenon_intro zenon_Hcf.
% 2.78/2.99  apply zenon_Hcf. zenon_intro zenon_Tz_ia. apply NNPP. zenon_intro zenon_Hd1.
% 2.78/2.99  apply (zenon_notimply_s _ _ zenon_Hd1). zenon_intro zenon_Hd3. zenon_intro zenon_Hd2.
% 2.78/2.99  apply (zenon_notimply_s _ _ zenon_Hd2). zenon_intro zenon_Hd5. zenon_intro zenon_Hd4.
% 2.78/2.99  generalize (axiom_16 zenon_Tx_hw). zenon_intro zenon_Hd6.
% 2.78/2.99  generalize (zenon_Hd6 zenon_Ty_hy). zenon_intro zenon_Hd7.
% 2.78/2.99  generalize (zenon_Hd7 zenon_Tz_ia). zenon_intro zenon_Hd8.
% 2.78/2.99  apply (zenon_imply_s _ _ zenon_Hd8); [ zenon_intro zenon_Hda | zenon_intro zenon_Hd9 ].
% 2.78/2.99  apply (zenon_notand_s _ _ zenon_Hda); [ zenon_intro zenon_Hdc | zenon_intro zenon_Hdb ].
% 2.78/2.99  exact (zenon_Hdc zenon_Hd3).
% 2.78/2.99  exact (zenon_Hdb zenon_Hd5).
% 2.78/2.99  exact (zenon_Hd4 zenon_Hd9).
% 2.78/2.99  Qed.
% 2.78/2.99  % SZS output end Proof
% 2.78/2.99  (* END-PROOF *)
% 2.78/2.99  nodes searched: 119904
% 2.78/2.99  max branch formulas: 4035
% 2.78/2.99  proof nodes created: 2120
% 2.78/2.99  formulas created: 259893
% 2.78/2.99  
%------------------------------------------------------------------------------