%------------------------------------------------------------------------------
% File     : ConnectPP---0.2.2
% Problem  : SET901+1 : TPTP v8.1.2. Released v3.2.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : connect++ --verbosity 0 --no-colour --tptp-proof --schedule default %s

% Computer : n012.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  : 300s
% DateTime : Wed Mar  6 09:19:58 EST 2024

% Result   : Theorem 0.93s 1.16s
% Output   : Proof 0.93s
% Verified : 
% SZS Type : -

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.00/0.12  % Problem  : SET901+1 : TPTP v8.1.2. Released v3.2.0.
% 0.12/0.12  % Command  : connect++ --verbosity 0 --no-colour --tptp-proof --schedule default %s
% 0.12/0.33  % Computer : n012.cluster.edu
% 0.12/0.33  % Model    : x86_64 x86_64
% 0.12/0.33  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.12/0.33  % Memory   : 8042.1875MB
% 0.12/0.33  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.12/0.33  % CPULimit : 300
% 0.12/0.33  % WCLimit  : 300
% 0.12/0.33  % DateTime : Sun Mar  3 19:19:39 EST 2024
% 0.12/0.33  % CPUTime  : 
% 0.93/1.16  % SZS status Theorem for theBenchmark
% 0.93/1.16  % SZS output start Proof for theBenchmark
% 0.93/1.16  
% 0.93/1.16  % Formula: commutativity_k2_tarski ( axiom ) converted to clauses:
% 0.93/1.16  cnf(commutativity_k2_tarski-1, axiom, ( ( unordered_pair(_u1, _u0) = unordered_pair(_u0, _u1)) )).
% 0.93/1.16  
% 0.93/1.16  % Formula: reflexivity_r1_tarski ( axiom ) converted to clauses:
% 0.93/1.16  cnf(reflexivity_r1_tarski-1, axiom, ( subset(_u3, _u3) )).
% 0.93/1.16  
% 0.93/1.16  % Formula: fc1_xboole_0 ( axiom ) converted to clauses:
% 0.93/1.16  cnf(fc1_xboole_0-1, axiom, ( empty(empty_set) )).
% 0.93/1.16  
% 0.93/1.16  % Formula: rc1_xboole_0 ( axiom ) converted to clauses:
% 0.93/1.16  cnf(rc1_xboole_0-1, axiom, ( empty(skolem1) )).
% 0.93/1.16  
% 0.93/1.16  % Formula: rc2_xboole_0 ( axiom ) converted to clauses:
% 0.93/1.16  cnf(rc2_xboole_0-1, axiom, ( ~empty(skolem2) )).
% 0.93/1.16  
% 0.93/1.16  % Formula: t42_zfmisc_1 ( conjecture ) converted to clauses:
% 0.93/1.16  cnf(t42_zfmisc_1-1, negated_conjecture, ( subset(skolem3, unordered_pair(skolem4, skolem5)) | ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-2, negated_conjecture, ( subset(skolem3, unordered_pair(skolem4, skolem5)) | ~subset(skolem6, unordered_pair(skolem7, skolem8)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-3, negated_conjecture, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != empty_set) )).
% 0.93/1.16  cnf(t42_zfmisc_1-4, negated_conjecture, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem4)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-5, negated_conjecture, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem5)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-6, negated_conjecture, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != unordered_pair(skolem4, skolem5)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-7, negated_conjecture, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != empty_set) )).
% 0.93/1.16  cnf(t42_zfmisc_1-8, negated_conjecture, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem4)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-9, negated_conjecture, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem5)) )).
% 0.93/1.16  cnf(t42_zfmisc_1-10, negated_conjecture, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != unordered_pair(skolem4, skolem5)) )).
% 0.93/1.16  
% 0.93/1.16  % Formula: l46_zfmisc_1 ( axiom ) converted to clauses:
% 0.93/1.16  cnf(l46_zfmisc_1-1, axiom, ( ~subset(_u22, unordered_pair(_u20, _u18)) | ( _u22 = empty_set) | ( _u22 = singleton(_u20)) | ( _u22 = singleton(_u18)) | ( _u22 = unordered_pair(_u20, _u18)) )).
% 0.93/1.16  cnf(l46_zfmisc_1-2, axiom, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != empty_set) )).
% 0.93/1.16  cnf(l46_zfmisc_1-3, axiom, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != singleton(_u21)) )).
% 0.93/1.16  cnf(l46_zfmisc_1-4, axiom, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != singleton(_u19)) )).
% 0.93/1.16  cnf(l46_zfmisc_1-5, axiom, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != unordered_pair(_u21, _u19)) )).
% 0.93/1.16  
% 0.93/1.16  % Problem matrix:
% 0.93/1.16  cnf(matrix-0, plain, ( ( __eqx_0 = __eqx_0) )).
% 0.93/1.16  cnf(matrix-1, plain, ( ( __eqx_0 != __eqx_1) | ( __eqx_1 = __eqx_0) )).
% 0.93/1.16  cnf(matrix-2, plain, ( ( __eqx_0 != __eqx_1) | ( __eqx_1 != __eqx_2) | ( __eqx_0 = __eqx_2) )).
% 0.93/1.16  cnf(matrix-3, plain, ( ( __eqx_0 != __eqy_0) | ( __eqx_1 != __eqy_1) | ( unordered_pair(__eqx_0, __eqx_1) = unordered_pair(__eqy_0, __eqy_1)) )).
% 0.93/1.16  cnf(matrix-4, plain, ( ( __eqx_0 != __eqy_0) | ( singleton(__eqx_0) = singleton(__eqy_0)) )).
% 0.93/1.16  cnf(matrix-5, plain, ( ( __eqx_0 != __eqy_0) | ( __eqx_1 != __eqy_1) | ~subset(__eqx_0, __eqx_1) | subset(__eqy_0, __eqy_1) )).
% 0.93/1.16  cnf(matrix-6, plain, ( ( __eqx_0 != __eqy_0) | ~empty(__eqx_0) | empty(__eqy_0) )).
% 0.93/1.16  cnf(matrix-7, plain, ( ( unordered_pair(_u1, _u0) = unordered_pair(_u0, _u1)) )).
% 0.93/1.16  cnf(matrix-8, plain, ( subset(_u3, _u3) )).
% 0.93/1.16  cnf(matrix-9, plain, ( empty(empty_set) )).
% 0.93/1.16  cnf(matrix-10, plain, ( empty(skolem1) )).
% 0.93/1.16  cnf(matrix-11, plain, ( ~empty(skolem2) )).
% 0.93/1.16  cnf(matrix-12, plain, ( subset(skolem3, unordered_pair(skolem4, skolem5)) | ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) )).
% 0.93/1.16  cnf(matrix-13, plain, ( subset(skolem3, unordered_pair(skolem4, skolem5)) | ~subset(skolem6, unordered_pair(skolem7, skolem8)) )).
% 0.93/1.16  cnf(matrix-14, plain, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != empty_set) )).
% 0.93/1.16  cnf(matrix-15, plain, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem4)) )).
% 0.93/1.16  cnf(matrix-16, plain, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem5)) )).
% 0.93/1.16  cnf(matrix-17, plain, ( ( skolem6 = empty_set) | ( skolem6 = singleton(skolem7)) | ( skolem6 = singleton(skolem8)) | ( skolem6 = unordered_pair(skolem7, skolem8)) | ( skolem3 != unordered_pair(skolem4, skolem5)) )).
% 0.93/1.16  cnf(matrix-18, plain, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != empty_set) )).
% 0.93/1.16  cnf(matrix-19, plain, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem4)) )).
% 0.93/1.16  cnf(matrix-20, plain, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != singleton(skolem5)) )).
% 0.93/1.16  cnf(matrix-21, plain, ( ~subset(skolem6, unordered_pair(skolem7, skolem8)) | ( skolem3 != unordered_pair(skolem4, skolem5)) )).
% 0.93/1.16  cnf(matrix-22, plain, ( ~subset(_u22, unordered_pair(_u20, _u18)) | ( _u22 = empty_set) | ( _u22 = singleton(_u20)) | ( _u22 = singleton(_u18)) | ( _u22 = unordered_pair(_u20, _u18)) )).
% 0.93/1.16  cnf(matrix-23, plain, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != empty_set) )).
% 0.93/1.16  cnf(matrix-24, plain, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != singleton(_u21)) )).
% 0.93/1.16  cnf(matrix-25, plain, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != singleton(_u19)) )).
% 0.93/1.16  cnf(matrix-26, plain, ( subset(_u23, unordered_pair(_u21, _u19)) | ( _u23 != unordered_pair(_u21, _u19)) )).
% 0.93/1.16  
% 0.93/1.16  % Proof stack:
% 0.93/1.16  cnf(proof-stack, plain, 
% 0.93/1.16  proof_stack(
% 0.93/1.16  start(18), 
% 0.93/1.16  left_branch(0, 24, 0, 2), 
% 0.93/1.16  left_branch(0, 17, 1, 3), 
% 0.93/1.16  left_branch(0, 23, 1, 4), 
% 0.93/1.16  reduction(0, 0), 
% 0.93/1.16  right_branch(4), 
% 0.93/1.16  left_branch(0, 26, 1, 5), 
% 0.93/1.16  reduction(0, 0), 
% 0.93/1.16  right_branch(5), 
% 0.93/1.16  left_branch(0, 25, 1, 6), 
% 0.93/1.16  reduction(0, 0), 
% 0.93/1.16  right_branch(6), 
% 0.93/1.16  left_branch(0, 22, 4, 7), 
% 0.93/1.16  left_branch(0, 12, 0, 8), 
% 0.93/1.16  lemmata(0, 1), 
% 0.93/1.16  lemmata(0, 2), 
% 0.93/1.16  reduction(0, 1), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  right_branch(8), 
% 0.93/1.16  left_branch(0, 16, 4, 9), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  lemmata(0, 1), 
% 0.93/1.16  lemmata(0, 2), 
% 0.93/1.16  reduction(0, 1), 
% 0.93/1.16  right_branch(9), 
% 0.93/1.16  left_branch(0, 15, 4, 10), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  lemmata(0, 1), 
% 0.93/1.16  lemmata(0, 2), 
% 0.93/1.16  reduction(0, 1), 
% 0.93/1.16  right_branch(10), 
% 0.93/1.16  left_branch(0, 14, 4, 11), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  lemmata(0, 1), 
% 0.93/1.16  lemmata(0, 2), 
% 0.93/1.16  reduction(0, 1), 
% 0.93/1.16  right_branch(11), 
% 0.93/1.16  right_branch(7), 
% 0.93/1.16  right_branch(3), 
% 0.93/1.16  right_branch(2), 
% 0.93/1.16  left_branch(0, 22, 1, 3), 
% 0.93/1.16  left_branch(0, 25, 0, 4), 
% 0.93/1.16  left_branch(0, 22, 3, 5), 
% 0.93/1.16  left_branch(0, 13, 0, 6), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  right_branch(6), 
% 0.93/1.16  left_branch(0, 26, 1, 7), 
% 0.93/1.16  reduction(0, 1), 
% 0.93/1.16  right_branch(7), 
% 0.93/1.16  left_branch(0, 24, 1, 8), 
% 0.93/1.16  reduction(0, 1), 
% 0.93/1.16  right_branch(8), 
% 0.93/1.16  reduction(0, 0), 
% 0.93/1.16  right_branch(5), 
% 0.93/1.16  right_branch(4), 
% 0.93/1.16  left_branch(0, 20, 1, 5), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  right_branch(5), 
% 0.93/1.16  left_branch(0, 19, 1, 6), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  right_branch(6), 
% 0.93/1.16  left_branch(0, 21, 1, 7), 
% 0.93/1.16  lemmata(0, 0), 
% 0.93/1.16  right_branch(7), 
% 0.93/1.16  right_branch(3)
% 0.93/1.16  )).
% 0.93/1.16  % SZS output end Proof for theBenchmark
%------------------------------------------------------------------------------