%------------------------------------------------------------------------------
% File     : Metis---2.4
% Problem  : SET917+1 : TPTP v8.1.0. Released v3.2.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : metis --show proof --show saturation %s

% Computer : n017.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 03:38:20 EDT 2022

% Result   : Theorem 0.14s 0.35s
% Output   : CNFRefutation 0.14s
% Verified : 
% SZS Type : Refutation
%            Derivation depth      :    9
%            Number of leaves      :    7
% Syntax   : Number of formulae    :   35 (  15 unt;   0 def)
%            Number of atoms       :   57 (  33 equ)
%            Maximal formula atoms :    3 (   1 avg)
%            Number of connectives :   46 (  24   ~;  16   |;   2   &)
%                                         (   0 <=>;   4  =>;   0  <=;   0 <~>)
%            Maximal formula depth :    6 (   3 avg)
%            Maximal term depth    :    3 (   1 avg)
%            Number of predicates  :    5 (   2 usr;   1 prp; 0-2 aty)
%            Number of functors    :    4 (   4 usr;   2 con; 0-2 aty)
%            Number of variables   :   41 (   0 sgn  24   !;   2   ?)

% Comments : 
%------------------------------------------------------------------------------
fof(commutativity_k3_xboole_0,axiom,
    ! [A,B] : set_intersection2(A,B) = set_intersection2(B,A) ).

fof(l28_zfmisc_1,axiom,
    ! [A,B] :
      ( ~ in(A,B)
     => disjoint(singleton(A),B) ) ).

fof(l32_zfmisc_1,axiom,
    ! [A,B] :
      ( in(A,B)
     => set_intersection2(B,singleton(A)) = singleton(A) ) ).

fof(t58_zfmisc_1,conjecture,
    ! [A,B] :
      ( disjoint(singleton(A),B)
      | set_intersection2(singleton(A),B) = singleton(A) ) ).

fof(subgoal_0,plain,
    ! [A,B] :
      ( ~ disjoint(singleton(A),B)
     => set_intersection2(singleton(A),B) = singleton(A) ),
    inference(strip,[],[t58_zfmisc_1]) ).

fof(negate_0_0,plain,
    ~ ! [A,B] :
        ( ~ disjoint(singleton(A),B)
       => set_intersection2(singleton(A),B) = singleton(A) ),
    inference(negate,[],[subgoal_0]) ).

fof(normalize_0_0,plain,
    ? [A,B] :
      ( set_intersection2(singleton(A),B) != singleton(A)
      & ~ disjoint(singleton(A),B) ),
    inference(canonicalize,[],[negate_0_0]) ).

fof(normalize_0_1,plain,
    ( set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) != singleton(skolemFOFtoCNF_A_2)
    & ~ disjoint(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) ),
    inference(skolemize,[],[normalize_0_0]) ).

fof(normalize_0_2,plain,
    ~ disjoint(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B),
    inference(conjunct,[],[normalize_0_1]) ).

fof(normalize_0_3,plain,
    ! [A,B] :
      ( disjoint(singleton(A),B)
      | in(A,B) ),
    inference(canonicalize,[],[l28_zfmisc_1]) ).

fof(normalize_0_4,plain,
    ! [A,B] :
      ( disjoint(singleton(A),B)
      | in(A,B) ),
    inference(specialize,[],[normalize_0_3]) ).

fof(normalize_0_5,plain,
    ! [A,B] :
      ( ~ in(A,B)
      | set_intersection2(B,singleton(A)) = singleton(A) ),
    inference(canonicalize,[],[l32_zfmisc_1]) ).

fof(normalize_0_6,plain,
    ! [A,B] :
      ( ~ in(A,B)
      | set_intersection2(B,singleton(A)) = singleton(A) ),
    inference(specialize,[],[normalize_0_5]) ).

fof(normalize_0_7,plain,
    set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) != singleton(skolemFOFtoCNF_A_2),
    inference(conjunct,[],[normalize_0_1]) ).

fof(normalize_0_8,plain,
    ! [A,B] : set_intersection2(A,B) = set_intersection2(B,A),
    inference(canonicalize,[],[commutativity_k3_xboole_0]) ).

fof(normalize_0_9,plain,
    ! [A,B] : set_intersection2(A,B) = set_intersection2(B,A),
    inference(specialize,[],[normalize_0_8]) ).

cnf(refute_0_0,plain,
    ~ disjoint(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B),
    inference(canonicalize,[],[normalize_0_2]) ).

cnf(refute_0_1,plain,
    ( disjoint(singleton(A),B)
    | in(A,B) ),
    inference(canonicalize,[],[normalize_0_4]) ).

cnf(refute_0_2,plain,
    ( disjoint(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B)
    | in(skolemFOFtoCNF_A_2,skolemFOFtoCNF_B) ),
    inference(subst,[],[refute_0_1:[bind(A,$fot(skolemFOFtoCNF_A_2)),bind(B,$fot(skolemFOFtoCNF_B))]]) ).

cnf(refute_0_3,plain,
    in(skolemFOFtoCNF_A_2,skolemFOFtoCNF_B),
    inference(resolve,[$cnf( disjoint(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) )],[refute_0_2,refute_0_0]) ).

cnf(refute_0_4,plain,
    ( ~ in(A,B)
    | set_intersection2(B,singleton(A)) = singleton(A) ),
    inference(canonicalize,[],[normalize_0_6]) ).

cnf(refute_0_5,plain,
    ( ~ in(skolemFOFtoCNF_A_2,skolemFOFtoCNF_B)
    | set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)) = singleton(skolemFOFtoCNF_A_2) ),
    inference(subst,[],[refute_0_4:[bind(A,$fot(skolemFOFtoCNF_A_2)),bind(B,$fot(skolemFOFtoCNF_B))]]) ).

cnf(refute_0_6,plain,
    set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)) = singleton(skolemFOFtoCNF_A_2),
    inference(resolve,[$cnf( in(skolemFOFtoCNF_A_2,skolemFOFtoCNF_B) )],[refute_0_3,refute_0_5]) ).

cnf(refute_0_7,plain,
    set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) != singleton(skolemFOFtoCNF_A_2),
    inference(canonicalize,[],[normalize_0_7]) ).

cnf(refute_0_8,plain,
    set_intersection2(A,B) = set_intersection2(B,A),
    inference(canonicalize,[],[normalize_0_9]) ).

cnf(refute_0_9,plain,
    X = X,
    introduced(tautology,[refl,[$fot(X)]]) ).

cnf(refute_0_10,plain,
    ( X != X
    | X != Y
    | Y = X ),
    introduced(tautology,[equality,[$cnf( $equal(X,X) ),[0],$fot(Y)]]) ).

cnf(refute_0_11,plain,
    ( X != Y
    | Y = X ),
    inference(resolve,[$cnf( $equal(X,X) )],[refute_0_9,refute_0_10]) ).

cnf(refute_0_12,plain,
    ( set_intersection2(A,B) != set_intersection2(B,A)
    | set_intersection2(B,A) = set_intersection2(A,B) ),
    inference(subst,[],[refute_0_11:[bind(X,$fot(set_intersection2(A,B))),bind(Y,$fot(set_intersection2(B,A)))]]) ).

cnf(refute_0_13,plain,
    set_intersection2(B,A) = set_intersection2(A,B),
    inference(resolve,[$cnf( $equal(set_intersection2(A,B),set_intersection2(B,A)) )],[refute_0_8,refute_0_12]) ).

cnf(refute_0_14,plain,
    set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) = set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)),
    inference(subst,[],[refute_0_13:[bind(A,$fot(skolemFOFtoCNF_B)),bind(B,$fot(singleton(skolemFOFtoCNF_A_2)))]]) ).

cnf(refute_0_15,plain,
    ( set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) != set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2))
    | set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)) != singleton(skolemFOFtoCNF_A_2)
    | set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) = singleton(skolemFOFtoCNF_A_2) ),
    introduced(tautology,[equality,[$cnf( ~ $equal(set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B),singleton(skolemFOFtoCNF_A_2)) ),[0],$fot(set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)))]]) ).

cnf(refute_0_16,plain,
    ( set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)) != singleton(skolemFOFtoCNF_A_2)
    | set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B) = singleton(skolemFOFtoCNF_A_2) ),
    inference(resolve,[$cnf( $equal(set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B),set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2))) )],[refute_0_14,refute_0_15]) ).

cnf(refute_0_17,plain,
    set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)) != singleton(skolemFOFtoCNF_A_2),
    inference(resolve,[$cnf( $equal(set_intersection2(singleton(skolemFOFtoCNF_A_2),skolemFOFtoCNF_B),singleton(skolemFOFtoCNF_A_2)) )],[refute_0_16,refute_0_7]) ).

cnf(refute_0_18,plain,
    $false,
    inference(resolve,[$cnf( $equal(set_intersection2(skolemFOFtoCNF_B,singleton(skolemFOFtoCNF_A_2)),singleton(skolemFOFtoCNF_A_2)) )],[refute_0_6,refute_0_17]) ).

%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.07/0.13  % Problem  : SET917+1 : TPTP v8.1.0. Released v3.2.0.
% 0.07/0.13  % Command  : metis --show proof --show saturation %s
% 0.14/0.34  % Computer : n017.cluster.edu
% 0.14/0.34  % Model    : x86_64 x86_64
% 0.14/0.34  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.14/0.34  % Memory   : 8042.1875MB
% 0.14/0.34  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.14/0.34  % CPULimit : 300
% 0.14/0.34  % WCLimit  : 600
% 0.14/0.34  % DateTime : Sun Jul 10 11:41:03 EDT 2022
% 0.14/0.34  % CPUTime  : 
% 0.14/0.35  %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% 0.14/0.35  % SZS status Theorem for /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.14/0.35  
% 0.14/0.35  % SZS output start CNFRefutation for /export/starexec/sandbox2/benchmark/theBenchmark.p
% See solution above
% 0.14/0.36  
%------------------------------------------------------------------------------