TSTP Solution File: KLE132+1 by SInE---0.4
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- Process Solution
%------------------------------------------------------------------------------
% File : SInE---0.4
% Problem : KLE132+1 : TPTP v5.0.0. Released v4.0.0.
% Transfm : none
% Format : tptp:raw
% Command : Source/sine.py -e eprover -t %d %s
% Computer : art03.cs.miami.edu
% Model : i686 i686
% CPU : Intel(R) Pentium(R) 4 CPU 2.80GHz @ 2793MHz
% Memory : 2018MB
% OS : Linux 2.6.26.8-57.fc8
% CPULimit : 300s
% DateTime : Sat Dec 25 12:32:31 EST 2010
% Result : Theorem 196.12s
% Output : CNFRefutation 196.12s
% Verified :
% SZS Type : Refutation
% Derivation depth : 20
% Number of leaves : 13
% Syntax : Number of formulae : 82 ( 76 unt; 0 def)
% Number of atoms : 94 ( 92 equ)
% Maximal formula atoms : 3 ( 1 avg)
% Number of connectives : 19 ( 7 ~; 0 |; 8 &)
% ( 0 <=>; 4 =>; 0 <=; 0 <~>)
% Maximal formula depth : 6 ( 2 avg)
% Maximal term depth : 16 ( 3 avg)
% Number of predicates : 2 ( 0 usr; 1 prp; 0-2 aty)
% Number of functors : 11 ( 11 usr; 4 con; 0-2 aty)
% Number of variables : 98 ( 1 sgn 48 !; 4 ?)
% Comments :
%------------------------------------------------------------------------------
fof(1,axiom,
! [X1,X2,X3] : multiplication(addition(X1,X2),X3) = addition(multiplication(X1,X3),multiplication(X2,X3)),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',left_distributivity) ).
fof(5,axiom,
! [X1] : multiplication(X1,zero) = zero,
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',right_annihilation) ).
fof(6,axiom,
! [X1] : multiplication(X1,one) = X1,
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',multiplicative_right_identity) ).
fof(7,axiom,
! [X4,X5] : domain_difference(X4,X5) = multiplication(domain(X4),antidomain(X5)),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',domain_difference) ).
fof(8,axiom,
! [X1] : multiplication(one,X1) = X1,
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',multiplicative_left_identity) ).
fof(9,axiom,
! [X4] : addition(antidomain(antidomain(X4)),antidomain(X4)) = one,
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',domain3) ).
fof(11,axiom,
! [X4] : multiplication(antidomain(X4),X4) = zero,
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',domain1) ).
fof(12,axiom,
! [X4] : domain(X4) = antidomain(antidomain(X4)),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',domain4) ).
fof(14,axiom,
! [X1] : addition(X1,zero) = X1,
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',additive_identity) ).
fof(17,axiom,
! [X4,X5] : forward_diamond(X4,X5) = domain(multiplication(X4,domain(X5))),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',forward_diamond) ).
fof(18,axiom,
! [X1,X2] : addition(X1,X2) = addition(X2,X1),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',additive_commutativity) ).
fof(22,axiom,
! [X1,X2,X3] : multiplication(X1,addition(X2,X3)) = addition(multiplication(X1,X2),multiplication(X1,X3)),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',right_distributivity) ).
fof(23,conjecture,
! [X4] :
( ! [X5] : addition(forward_diamond(X4,domain(X5)),forward_diamond(star(X4),domain_difference(domain(X5),forward_diamond(X4,domain(X5))))) = forward_diamond(star(X4),domain_difference(domain(X5),forward_diamond(X4,domain(X5))))
=> ! [X6] :
( addition(domain(X6),forward_diamond(X4,domain(X6))) = forward_diamond(X4,domain(X6))
=> domain(X6) = zero ) ),
file('/tmp/tmph3pWYa/sel_KLE132+1.p_4',goals) ).
fof(24,negated_conjecture,
~ ! [X4] :
( ! [X5] : addition(forward_diamond(X4,domain(X5)),forward_diamond(star(X4),domain_difference(domain(X5),forward_diamond(X4,domain(X5))))) = forward_diamond(star(X4),domain_difference(domain(X5),forward_diamond(X4,domain(X5))))
=> ! [X6] :
( addition(domain(X6),forward_diamond(X4,domain(X6))) = forward_diamond(X4,domain(X6))
=> domain(X6) = zero ) ),
inference(assume_negation,[status(cth)],[23]) ).
fof(25,plain,
! [X4,X5,X6] : multiplication(addition(X4,X5),X6) = addition(multiplication(X4,X6),multiplication(X5,X6)),
inference(variable_rename,[status(thm)],[1]) ).
cnf(26,plain,
multiplication(addition(X1,X2),X3) = addition(multiplication(X1,X3),multiplication(X2,X3)),
inference(split_conjunct,[status(thm)],[25]) ).
fof(33,plain,
! [X2] : multiplication(X2,zero) = zero,
inference(variable_rename,[status(thm)],[5]) ).
cnf(34,plain,
multiplication(X1,zero) = zero,
inference(split_conjunct,[status(thm)],[33]) ).
fof(35,plain,
! [X2] : multiplication(X2,one) = X2,
inference(variable_rename,[status(thm)],[6]) ).
cnf(36,plain,
multiplication(X1,one) = X1,
inference(split_conjunct,[status(thm)],[35]) ).
fof(37,plain,
! [X6,X7] : domain_difference(X6,X7) = multiplication(domain(X6),antidomain(X7)),
inference(variable_rename,[status(thm)],[7]) ).
cnf(38,plain,
domain_difference(X1,X2) = multiplication(domain(X1),antidomain(X2)),
inference(split_conjunct,[status(thm)],[37]) ).
fof(39,plain,
! [X2] : multiplication(one,X2) = X2,
inference(variable_rename,[status(thm)],[8]) ).
cnf(40,plain,
multiplication(one,X1) = X1,
inference(split_conjunct,[status(thm)],[39]) ).
fof(41,plain,
! [X5] : addition(antidomain(antidomain(X5)),antidomain(X5)) = one,
inference(variable_rename,[status(thm)],[9]) ).
cnf(42,plain,
addition(antidomain(antidomain(X1)),antidomain(X1)) = one,
inference(split_conjunct,[status(thm)],[41]) ).
fof(45,plain,
! [X5] : multiplication(antidomain(X5),X5) = zero,
inference(variable_rename,[status(thm)],[11]) ).
cnf(46,plain,
multiplication(antidomain(X1),X1) = zero,
inference(split_conjunct,[status(thm)],[45]) ).
fof(47,plain,
! [X5] : domain(X5) = antidomain(antidomain(X5)),
inference(variable_rename,[status(thm)],[12]) ).
cnf(48,plain,
domain(X1) = antidomain(antidomain(X1)),
inference(split_conjunct,[status(thm)],[47]) ).
fof(51,plain,
! [X2] : addition(X2,zero) = X2,
inference(variable_rename,[status(thm)],[14]) ).
cnf(52,plain,
addition(X1,zero) = X1,
inference(split_conjunct,[status(thm)],[51]) ).
fof(57,plain,
! [X6,X7] : forward_diamond(X6,X7) = domain(multiplication(X6,domain(X7))),
inference(variable_rename,[status(thm)],[17]) ).
cnf(58,plain,
forward_diamond(X1,X2) = domain(multiplication(X1,domain(X2))),
inference(split_conjunct,[status(thm)],[57]) ).
fof(59,plain,
! [X3,X4] : addition(X3,X4) = addition(X4,X3),
inference(variable_rename,[status(thm)],[18]) ).
cnf(60,plain,
addition(X1,X2) = addition(X2,X1),
inference(split_conjunct,[status(thm)],[59]) ).
fof(68,plain,
! [X4,X5,X6] : multiplication(X4,addition(X5,X6)) = addition(multiplication(X4,X5),multiplication(X4,X6)),
inference(variable_rename,[status(thm)],[22]) ).
cnf(69,plain,
multiplication(X1,addition(X2,X3)) = addition(multiplication(X1,X2),multiplication(X1,X3)),
inference(split_conjunct,[status(thm)],[68]) ).
fof(70,negated_conjecture,
? [X4] :
( ! [X5] : addition(forward_diamond(X4,domain(X5)),forward_diamond(star(X4),domain_difference(domain(X5),forward_diamond(X4,domain(X5))))) = forward_diamond(star(X4),domain_difference(domain(X5),forward_diamond(X4,domain(X5))))
& ? [X6] :
( addition(domain(X6),forward_diamond(X4,domain(X6))) = forward_diamond(X4,domain(X6))
& domain(X6) != zero ) ),
inference(fof_nnf,[status(thm)],[24]) ).
fof(71,negated_conjecture,
? [X7] :
( ! [X8] : addition(forward_diamond(X7,domain(X8)),forward_diamond(star(X7),domain_difference(domain(X8),forward_diamond(X7,domain(X8))))) = forward_diamond(star(X7),domain_difference(domain(X8),forward_diamond(X7,domain(X8))))
& ? [X9] :
( addition(domain(X9),forward_diamond(X7,domain(X9))) = forward_diamond(X7,domain(X9))
& domain(X9) != zero ) ),
inference(variable_rename,[status(thm)],[70]) ).
fof(72,negated_conjecture,
( ! [X8] : addition(forward_diamond(esk1_0,domain(X8)),forward_diamond(star(esk1_0),domain_difference(domain(X8),forward_diamond(esk1_0,domain(X8))))) = forward_diamond(star(esk1_0),domain_difference(domain(X8),forward_diamond(esk1_0,domain(X8))))
& addition(domain(esk2_0),forward_diamond(esk1_0,domain(esk2_0))) = forward_diamond(esk1_0,domain(esk2_0))
& domain(esk2_0) != zero ),
inference(skolemize,[status(esa)],[71]) ).
fof(73,negated_conjecture,
! [X8] :
( addition(forward_diamond(esk1_0,domain(X8)),forward_diamond(star(esk1_0),domain_difference(domain(X8),forward_diamond(esk1_0,domain(X8))))) = forward_diamond(star(esk1_0),domain_difference(domain(X8),forward_diamond(esk1_0,domain(X8))))
& addition(domain(esk2_0),forward_diamond(esk1_0,domain(esk2_0))) = forward_diamond(esk1_0,domain(esk2_0))
& domain(esk2_0) != zero ),
inference(shift_quantors,[status(thm)],[72]) ).
cnf(74,negated_conjecture,
domain(esk2_0) != zero,
inference(split_conjunct,[status(thm)],[73]) ).
cnf(75,negated_conjecture,
addition(domain(esk2_0),forward_diamond(esk1_0,domain(esk2_0))) = forward_diamond(esk1_0,domain(esk2_0)),
inference(split_conjunct,[status(thm)],[73]) ).
cnf(76,negated_conjecture,
addition(forward_diamond(esk1_0,domain(X1)),forward_diamond(star(esk1_0),domain_difference(domain(X1),forward_diamond(esk1_0,domain(X1))))) = forward_diamond(star(esk1_0),domain_difference(domain(X1),forward_diamond(esk1_0,domain(X1)))),
inference(split_conjunct,[status(thm)],[73]) ).
cnf(77,plain,
antidomain(antidomain(multiplication(X1,antidomain(antidomain(X2))))) = forward_diamond(X1,X2),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[58,48,theory(equality)]),48,theory(equality)]),
[unfolding] ).
cnf(78,plain,
multiplication(antidomain(antidomain(X1)),antidomain(X2)) = domain_difference(X1,X2),
inference(rw,[status(thm)],[38,48,theory(equality)]),
[unfolding] ).
cnf(79,negated_conjecture,
addition(antidomain(antidomain(esk2_0)),forward_diamond(esk1_0,antidomain(antidomain(esk2_0)))) = forward_diamond(esk1_0,antidomain(antidomain(esk2_0))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[75,48,theory(equality)]),48,theory(equality)]),48,theory(equality)]),
[unfolding] ).
cnf(80,negated_conjecture,
addition(forward_diamond(esk1_0,antidomain(antidomain(X1))),forward_diamond(star(esk1_0),domain_difference(antidomain(antidomain(X1)),forward_diamond(esk1_0,antidomain(antidomain(X1)))))) = forward_diamond(star(esk1_0),domain_difference(antidomain(antidomain(X1)),forward_diamond(esk1_0,antidomain(antidomain(X1))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[76,48,theory(equality)]),48,theory(equality)]),48,theory(equality)]),48,theory(equality)]),48,theory(equality)]),
[unfolding] ).
cnf(82,negated_conjecture,
antidomain(antidomain(esk2_0)) != zero,
inference(rw,[status(thm)],[74,48,theory(equality)]),
[unfolding] ).
cnf(84,negated_conjecture,
addition(antidomain(antidomain(esk2_0)),antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(esk2_0)))))))) = antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(esk2_0))))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[79,77,theory(equality)]),77,theory(equality)]),
[unfolding] ).
cnf(85,negated_conjecture,
addition(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1))))))),antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(domain_difference(antidomain(antidomain(X1)),antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1)))))))))))))) = antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(domain_difference(antidomain(antidomain(X1)),antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1))))))))))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[80,77,theory(equality)]),77,theory(equality)]),77,theory(equality)]),77,theory(equality)]),77,theory(equality)]),
[unfolding] ).
cnf(87,negated_conjecture,
addition(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1))))))),antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(multiplication(antidomain(antidomain(antidomain(antidomain(X1)))),antidomain(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1))))))))))))))) = antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(multiplication(antidomain(antidomain(antidomain(antidomain(X1)))),antidomain(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1)))))))))))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[85,78,theory(equality)]),78,theory(equality)]),
[unfolding] ).
cnf(89,plain,
zero = antidomain(one),
inference(spm,[status(thm)],[36,46,theory(equality)]) ).
cnf(90,plain,
addition(zero,X1) = X1,
inference(spm,[status(thm)],[52,60,theory(equality)]) ).
cnf(134,plain,
addition(antidomain(X1),antidomain(antidomain(X1))) = one,
inference(rw,[status(thm)],[42,60,theory(equality)]) ).
cnf(148,plain,
addition(multiplication(antidomain(X1),X2),zero) = multiplication(antidomain(X1),addition(X2,X1)),
inference(spm,[status(thm)],[69,46,theory(equality)]) ).
cnf(167,plain,
multiplication(antidomain(X1),X2) = multiplication(antidomain(X1),addition(X2,X1)),
inference(rw,[status(thm)],[148,52,theory(equality)]) ).
cnf(186,plain,
addition(multiplication(X1,X2),zero) = multiplication(addition(X1,antidomain(X2)),X2),
inference(spm,[status(thm)],[26,46,theory(equality)]) ).
cnf(206,plain,
multiplication(X1,X2) = multiplication(addition(X1,antidomain(X2)),X2),
inference(rw,[status(thm)],[186,52,theory(equality)]) ).
cnf(286,plain,
addition(zero,antidomain(zero)) = one,
inference(spm,[status(thm)],[134,89,theory(equality)]) ).
cnf(312,plain,
antidomain(zero) = one,
inference(rw,[status(thm)],[286,90,theory(equality)]) ).
cnf(671,plain,
multiplication(addition(antidomain(X2),X1),X2) = multiplication(X1,X2),
inference(spm,[status(thm)],[206,60,theory(equality)]) ).
cnf(1089,plain,
multiplication(one,X1) = multiplication(antidomain(antidomain(X1)),X1),
inference(spm,[status(thm)],[671,134,theory(equality)]) ).
cnf(1118,plain,
X1 = multiplication(antidomain(antidomain(X1)),X1),
inference(rw,[status(thm)],[1089,40,theory(equality)]) ).
cnf(2106,plain,
multiplication(antidomain(antidomain(antidomain(X1))),one) = multiplication(antidomain(antidomain(antidomain(X1))),antidomain(X1)),
inference(spm,[status(thm)],[167,134,theory(equality)]) ).
cnf(2150,plain,
antidomain(antidomain(antidomain(X1))) = multiplication(antidomain(antidomain(antidomain(X1))),antidomain(X1)),
inference(rw,[status(thm)],[2106,36,theory(equality)]) ).
cnf(2151,plain,
antidomain(antidomain(antidomain(X1))) = antidomain(X1),
inference(rw,[status(thm)],[2150,1118,theory(equality)]) ).
cnf(2217,negated_conjecture,
addition(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(X1))))),antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(multiplication(antidomain(antidomain(X1)),antidomain(multiplication(esk1_0,antidomain(antidomain(X1))))))))))) = antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(multiplication(antidomain(antidomain(antidomain(antidomain(X1)))),antidomain(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(X1)))))))))))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[87,2151,theory(equality)]),2151,theory(equality)]),2151,theory(equality)]),2151,theory(equality)]) ).
cnf(2218,negated_conjecture,
addition(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(X1))))),antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(multiplication(antidomain(antidomain(X1)),antidomain(multiplication(esk1_0,antidomain(antidomain(X1))))))))))) = antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(multiplication(antidomain(antidomain(X1)),antidomain(multiplication(esk1_0,antidomain(antidomain(X1)))))))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[2217,2151,theory(equality)]),2151,theory(equality)]),2151,theory(equality)]) ).
cnf(2219,negated_conjecture,
addition(antidomain(antidomain(esk2_0)),antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0)))))) = antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(antidomain(antidomain(esk2_0))))))),
inference(rw,[status(thm)],[84,2151,theory(equality)]) ).
cnf(2220,negated_conjecture,
addition(antidomain(antidomain(esk2_0)),antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0)))))) = antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))),
inference(rw,[status(thm)],[2219,2151,theory(equality)]) ).
cnf(218188,negated_conjecture,
multiplication(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))),antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))) = multiplication(antidomain(antidomain(esk2_0)),antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))),
inference(spm,[status(thm)],[206,2220,theory(equality)]) ).
cnf(218313,negated_conjecture,
zero = multiplication(antidomain(antidomain(esk2_0)),antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))),
inference(rw,[status(thm)],[218188,46,theory(equality)]) ).
cnf(384296,negated_conjecture,
addition(antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))),antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(zero)))))) = antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(zero))))),
inference(spm,[status(thm)],[2218,218313,theory(equality)]) ).
cnf(384545,negated_conjecture,
antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))) = antidomain(antidomain(multiplication(star(esk1_0),antidomain(antidomain(zero))))),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[384296,312,theory(equality)]),89,theory(equality)]),34,theory(equality)]),312,theory(equality)]),89,theory(equality)]),52,theory(equality)]) ).
cnf(384546,negated_conjecture,
antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))) = zero,
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[384545,312,theory(equality)]),89,theory(equality)]),34,theory(equality)]),312,theory(equality)]),89,theory(equality)]) ).
cnf(385021,negated_conjecture,
addition(antidomain(antidomain(esk2_0)),zero) = antidomain(antidomain(multiplication(esk1_0,antidomain(antidomain(esk2_0))))),
inference(rw,[status(thm)],[2220,384546,theory(equality)]) ).
cnf(385022,negated_conjecture,
addition(antidomain(antidomain(esk2_0)),zero) = zero,
inference(rw,[status(thm)],[385021,384546,theory(equality)]) ).
cnf(385023,negated_conjecture,
antidomain(antidomain(esk2_0)) = zero,
inference(rw,[status(thm)],[385022,52,theory(equality)]) ).
cnf(385024,negated_conjecture,
$false,
inference(sr,[status(thm)],[385023,82,theory(equality)]) ).
cnf(385025,negated_conjecture,
$false,
385024,
[proof] ).
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% % SZS status Started for /home/graph/tptp/TPTP/Problems/KLE/KLE132+1.p
% --creating new selector for [KLE001+7.ax, KLE001+0.ax, KLE001+4.ax, KLE001+6.ax]
% eprover: CPU time limit exceeded, terminating
% eprover: CPU time limit exceeded, terminating
% -running prover on /tmp/tmph3pWYa/sel_KLE132+1.p_1 with time limit 29
% -prover status ResourceOut
% -running prover on /tmp/tmph3pWYa/sel_KLE132+1.p_2 with time limit 80
% -prover status ResourceOut
% --creating new selector for [KLE001+7.ax, KLE001+0.ax, KLE001+4.ax, KLE001+6.ax]
% eprover: CPU time limit exceeded, terminating
% -running prover on /tmp/tmph3pWYa/sel_KLE132+1.p_3 with time limit 75
% -prover status ResourceOut
% --creating new selector for [KLE001+7.ax, KLE001+0.ax, KLE001+4.ax, KLE001+6.ax]
% -running prover on /tmp/tmph3pWYa/sel_KLE132+1.p_4 with time limit 55
% -prover status Theorem
% Problem KLE132+1.p solved in phase 3.
% % SZS status Theorem for /home/graph/tptp/TPTP/Problems/KLE/KLE132+1.p
% % SZS status Ended for /home/graph/tptp/TPTP/Problems/KLE/KLE132+1.p
% Solved 1 out of 1.
% # Problem is unsatisfiable (or provable), constructing proof object
% # SZS status Theorem
% # SZS output start CNFRefutation.
% See solution above
% # SZS output end CNFRefutation
%
%------------------------------------------------------------------------------