TSTP Solution File: SEU189+2 by Zenon---0.7.1

%------------------------------------------------------------------------------
% File     : Zenon---0.7.1
% Problem  : SEU189+2 : TPTP v8.1.0. Released v3.3.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : run_zenon %s %d

% Computer : n028.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 : Tue Jul 19 16:00:06 EDT 2022

% Result   : Theorem 13.22s 13.41s
% Output   : Proof 13.22s
% Verified : 
% SZS Type : -

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.07/0.12  % Problem  : SEU189+2 : TPTP v8.1.0. Released v3.3.0.
% 0.07/0.13  % Command  : run_zenon %s %d
% 0.12/0.34  % Computer : n028.cluster.edu
% 0.12/0.34  % Model    : x86_64 x86_64
% 0.12/0.34  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.12/0.34  % Memory   : 8042.1875MB
% 0.12/0.34  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.12/0.34  % CPULimit : 300
% 0.12/0.34  % WCLimit  : 600
% 0.12/0.34  % DateTime : Sun Jun 19 12:26:45 EDT 2022
% 0.12/0.34  % CPUTime  : 
% 13.22/13.41  Zenon warning: unused variable (B : zenon_U) in idempotence_k2_xboole_0
% 13.22/13.41  Zenon warning: unused variable (B : zenon_U) in idempotence_k3_xboole_0
% 13.22/13.41  Zenon warning: unused variable (B : zenon_U) in irreflexivity_r2_xboole_0
% 13.22/13.41  Zenon warning: unused variable (B : zenon_U) in reflexivity_r1_tarski
% 13.22/13.41  (* PROOF-FOUND *)
% 13.22/13.41  % SZS status Theorem
% 13.22/13.41  (* BEGIN-PROOF *)
% 13.22/13.41  % SZS output start Proof
% 13.22/13.41  Theorem t65_relat_1 : (forall A : zenon_U, ((relation A)->(((relation_dom A) = (empty_set))<->((relation_rng A) = (empty_set))))).
% 13.22/13.41  Proof.
% 13.22/13.41  assert (zenon_L1_ : forall (zenon_TA_fx : zenon_U), (forall B : zenon_U, (~((in B zenon_TA_fx)/\(forall C : zenon_U, (forall D : zenon_U, (~(B = (ordered_pair C D)))))))) -> (~(relation zenon_TA_fx)) -> False).
% 13.22/13.41  do 1 intro. intros zenon_H97 zenon_H98.
% 13.22/13.41  generalize (d1_relat_1 zenon_TA_fx). zenon_intro zenon_H9a.
% 13.22/13.41  apply (zenon_equiv_s _ _ zenon_H9a); [ zenon_intro zenon_H98; zenon_intro zenon_H9c | zenon_intro zenon_H9b; zenon_intro zenon_H97 ].
% 13.22/13.41  exact (zenon_H9c zenon_H97).
% 13.22/13.41  exact (zenon_H98 zenon_H9b).
% 13.22/13.41  (* end of lemma zenon_L1_ *)
% 13.22/13.41  assert (zenon_L2_ : (~((empty_set) = (empty_set))) -> False).
% 13.22/13.41  do 0 intro. intros zenon_H9d.
% 13.22/13.41  apply zenon_H9d. apply refl_equal.
% 13.22/13.41  (* end of lemma zenon_L2_ *)
% 13.22/13.41  apply NNPP. intro zenon_G.
% 13.22/13.41  apply (zenon_and_s _ _ t60_relat_1). zenon_intro zenon_H9f. zenon_intro zenon_H9e.
% 13.22/13.41  apply (zenon_notallex_s (fun A : zenon_U => ((relation A)->(((relation_dom A) = (empty_set))<->((relation_rng A) = (empty_set))))) zenon_G); [ zenon_intro zenon_Ha0; idtac ].
% 13.22/13.41  elim zenon_Ha0. zenon_intro zenon_TA_fx. zenon_intro zenon_Ha1.
% 13.22/13.41  apply (zenon_notimply_s _ _ zenon_Ha1). zenon_intro zenon_H9b. zenon_intro zenon_Ha2.
% 13.22/13.41  generalize (d1_relat_1 zenon_TA_fx). zenon_intro zenon_H9a.
% 13.22/13.41  apply (zenon_equiv_s _ _ zenon_H9a); [ zenon_intro zenon_H98; zenon_intro zenon_H9c | zenon_intro zenon_H9b; zenon_intro zenon_H97 ].
% 13.22/13.41  exact (zenon_H98 zenon_H9b).
% 13.22/13.41  apply (zenon_notequiv_s _ _ zenon_Ha2); [ zenon_intro zenon_Ha6; zenon_intro zenon_Ha5 | zenon_intro zenon_Ha4; zenon_intro zenon_Ha3 ].
% 13.22/13.41  cut (((relation_dom (empty_set)) = (empty_set)) = ((relation_dom zenon_TA_fx) = (empty_set))).
% 13.22/13.41  intro zenon_D_pnotp.
% 13.22/13.41  apply zenon_Ha6.
% 13.22/13.41  rewrite <- zenon_D_pnotp.
% 13.22/13.41  exact zenon_H9f.
% 13.22/13.41  cut (((empty_set) = (empty_set))); [idtac | apply NNPP; zenon_intro zenon_H9d].
% 13.22/13.41  cut (((relation_dom (empty_set)) = (relation_dom zenon_TA_fx))); [idtac | apply NNPP; zenon_intro zenon_Ha7].
% 13.22/13.41  congruence.
% 13.22/13.41  elim (classic ((relation_dom zenon_TA_fx) = (relation_dom zenon_TA_fx))); [ zenon_intro zenon_Ha8 | zenon_intro zenon_Ha9 ].
% 13.22/13.41  cut (((relation_dom zenon_TA_fx) = (relation_dom zenon_TA_fx)) = ((relation_dom (empty_set)) = (relation_dom zenon_TA_fx))).
% 13.22/13.41  intro zenon_D_pnotp.
% 13.22/13.41  apply zenon_Ha7.
% 13.22/13.41  rewrite <- zenon_D_pnotp.
% 13.22/13.41  exact zenon_Ha8.
% 13.22/13.41  cut (((relation_dom zenon_TA_fx) = (relation_dom zenon_TA_fx))); [idtac | apply NNPP; zenon_intro zenon_Ha9].
% 13.22/13.41  cut (((relation_dom zenon_TA_fx) = (relation_dom (empty_set)))); [idtac | apply NNPP; zenon_intro zenon_Haa].
% 13.22/13.41  congruence.
% 13.22/13.41  cut ((zenon_TA_fx = (empty_set))); [idtac | apply NNPP; zenon_intro zenon_Hab].
% 13.22/13.41  congruence.
% 13.22/13.41  generalize (t64_relat_1 zenon_TA_fx). zenon_intro zenon_Hac.
% 13.22/13.42  apply (zenon_imply_s _ _ zenon_Hac); [ zenon_intro zenon_H98 | zenon_intro zenon_Had ].
% 13.22/13.42  apply (zenon_L1_ zenon_TA_fx); trivial.
% 13.22/13.42  apply (zenon_imply_s _ _ zenon_Had); [ zenon_intro zenon_Haf | zenon_intro zenon_Hae ].
% 13.22/13.42  apply (zenon_notor_s _ _ zenon_Haf). zenon_intro zenon_Ha6. zenon_intro zenon_Ha3.
% 13.22/13.42  exact (zenon_Ha3 zenon_Ha5).
% 13.22/13.42  exact (zenon_Hab zenon_Hae).
% 13.22/13.42  apply zenon_Ha9. apply refl_equal.
% 13.22/13.42  apply zenon_Ha9. apply refl_equal.
% 13.22/13.42  apply zenon_H9d. apply refl_equal.
% 13.22/13.42  cut (((relation_rng (empty_set)) = (empty_set)) = ((relation_rng zenon_TA_fx) = (empty_set))).
% 13.22/13.42  intro zenon_D_pnotp.
% 13.22/13.42  apply zenon_Ha3.
% 13.22/13.42  rewrite <- zenon_D_pnotp.
% 13.22/13.42  exact zenon_H9e.
% 13.22/13.42  cut (((empty_set) = (empty_set))); [idtac | apply NNPP; zenon_intro zenon_H9d].
% 13.22/13.42  cut (((relation_rng (empty_set)) = (relation_rng zenon_TA_fx))); [idtac | apply NNPP; zenon_intro zenon_Hb0].
% 13.22/13.42  congruence.
% 13.22/13.42  elim (classic ((relation_rng zenon_TA_fx) = (relation_rng zenon_TA_fx))); [ zenon_intro zenon_Hb1 | zenon_intro zenon_Hb2 ].
% 13.22/13.42  cut (((relation_rng zenon_TA_fx) = (relation_rng zenon_TA_fx)) = ((relation_rng (empty_set)) = (relation_rng zenon_TA_fx))).
% 13.22/13.43  intro zenon_D_pnotp.
% 13.22/13.43  apply zenon_Hb0.
% 13.22/13.43  rewrite <- zenon_D_pnotp.
% 13.22/13.43  exact zenon_Hb1.
% 13.22/13.43  cut (((relation_rng zenon_TA_fx) = (relation_rng zenon_TA_fx))); [idtac | apply NNPP; zenon_intro zenon_Hb2].
% 13.22/13.43  cut (((relation_rng zenon_TA_fx) = (relation_rng (empty_set)))); [idtac | apply NNPP; zenon_intro zenon_Hb3].
% 13.22/13.43  congruence.
% 13.22/13.43  cut ((zenon_TA_fx = (empty_set))); [idtac | apply NNPP; zenon_intro zenon_Hab].
% 13.22/13.43  congruence.
% 13.22/13.43  generalize (t64_relat_1 zenon_TA_fx). zenon_intro zenon_Hac.
% 13.22/13.43  apply (zenon_imply_s _ _ zenon_Hac); [ zenon_intro zenon_H98 | zenon_intro zenon_Had ].
% 13.22/13.43  apply (zenon_L1_ zenon_TA_fx); trivial.
% 13.22/13.43  apply (zenon_imply_s _ _ zenon_Had); [ zenon_intro zenon_Haf | zenon_intro zenon_Hae ].
% 13.22/13.43  apply (zenon_notor_s _ _ zenon_Haf). zenon_intro zenon_Ha6. zenon_intro zenon_Ha3.
% 13.22/13.43  exact (zenon_Ha6 zenon_Ha4).
% 13.22/13.43  exact (zenon_Hab zenon_Hae).
% 13.22/13.43  apply zenon_Hb2. apply refl_equal.
% 13.22/13.43  apply zenon_Hb2. apply refl_equal.
% 13.22/13.43  apply zenon_H9d. apply refl_equal.
% 13.22/13.43  Qed.
% 13.22/13.43  % SZS output end Proof
% 13.22/13.43  (* END-PROOF *)
% 13.22/13.43  nodes searched: 929942
% 13.22/13.43  max branch formulas: 35082
% 13.22/13.43  proof nodes created: 7269
% 13.22/13.43  formulas created: 945730
% 13.22/13.43  
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