TSTP Solution File: GRP593-1 by MaedMax---1.4

%------------------------------------------------------------------------------
% File     : MaedMax---1.4
% Problem  : GRP593-1 : TPTP v8.1.0. Released v2.6.0.
% Transfm  : none
% Format   : tptp
% Command  : run_maedmax %d %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 : Tue Jul 26 07:02:58 EDT 2022

% Result   : Unsatisfiable 0.76s 0.93s
% Output   : CNFRefutation 0.76s
% Verified : 
% SZS Type : Refutation
%            Derivation depth      :   17
%            Number of leaves      :    3
% Syntax   : Number of clauses     :   49 (  49 unt;   0 nHn;   7 RR)
%            Number of literals    :   49 (  48 equ;   6 neg)
%            Maximal clause size   :    1 (   1 avg)
%            Maximal term depth    :   11 (   2 avg)
%            Number of predicates  :    2 (   0 usr;   1 prp; 0-2 aty)
%            Number of functors    :   10 (  10 usr;   7 con; 0-2 aty)
%            Number of variables   :  114 (   0 sgn)

% Comments : 
%------------------------------------------------------------------------------
cnf(eq_0,axiom,
    A = inverse(double_divide(double_divide(B,C),inverse(double_divide(B,inverse(double_divide(A,C)))))),
    file('/tmp/MaedMax_4734') ).

cnf(eq_1,axiom,
    inverse(double_divide(A,B)) = multiply(B,A),
    file('/tmp/MaedMax_4734') ).

cnf(eq_2,negated_conjecture,
    multiply(inverse(a1),a1) != multiply(inverse(b1),b1),
    file('/tmp/MaedMax_4734') ).

cnf(eq_3,negated_conjecture,
    inverse(double_divide(a1,inverse(a1))) != inverse(double_divide(b1,inverse(b1))),
    inference(rw,[status(thm)],[inference(rw,[status(thm)],[eq_2,eq_1]),eq_1]) ).

cnf(eq_4,plain,
    inverse(double_divide(double_divide(double_divide(B,C),inverse(double_divide(A,C))),A)) = B,
    inference(cp,[status(thm)],[eq_0,eq_0]) ).

cnf(eq_5,plain,
    inverse(double_divide(double_divide(x100,inverse(double_divide(B,inverse(double_divide(A,C))))),inverse(double_divide(x100,A)))) = double_divide(B,C),
    inference(cp,[status(thm)],[eq_0,eq_0]) ).

cnf(eq_6,plain,
    A = inverse(double_divide(double_divide(double_divide(A,B),inverse(double_divide(C,B))),C)),
    eq_4 ).

cnf(eq_7,plain,
    double_divide(A,B) = inverse(double_divide(double_divide(C,inverse(double_divide(A,inverse(double_divide(x3,B))))),inverse(double_divide(C,x3)))),
    eq_5 ).

cnf(eq_8,plain,
    A = multiply(B,double_divide(double_divide(A,C),multiply(C,B))),
    inference(rw,[status(thm)],[inference(rw,[status(thm)],[eq_6,eq_1]),eq_1]) ).

cnf(eq_9,plain,
    inverse(double_divide(double_divide(double_divide(double_divide(A,B),inverse(double_divide(inverse(double_divide(x102,x101)),B))),x101),A)) = x102,
    inference(cp,[status(thm)],[eq_6,eq_0]) ).

cnf(eq_10,plain,
    inverse(double_divide(double_divide(x100,C),inverse(double_divide(x100,A)))) = double_divide(double_divide(A,B),inverse(double_divide(C,B))),
    inference(cp,[status(thm)],[eq_6,eq_0]) ).

cnf(eq_11,plain,
    A = double_divide(inverse(double_divide(double_divide(A,inverse(double_divide(x102,x103))),x102)),x103),
    inference(cp,[status(thm)],[eq_6,eq_7]) ).

cnf(eq_12,plain,
    double_divide(double_divide(A,B),inverse(double_divide(C,B))) = inverse(double_divide(double_divide(x3,C),inverse(double_divide(x3,A)))),
    eq_10 ).

cnf(eq_13,plain,
    A = inverse(double_divide(double_divide(double_divide(double_divide(B,C),inverse(double_divide(inverse(double_divide(A,x3)),C))),x3),B)),
    eq_9 ).

cnf(eq_14,plain,
    A = double_divide(inverse(double_divide(double_divide(A,inverse(double_divide(B,C))),B)),C),
    eq_11 ).

cnf(eq_15,plain,
    double_divide(double_divide(A,B),multiply(B,C)) = multiply(multiply(A,x3),double_divide(x3,C)),
    inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[eq_12,eq_1]),eq_1]),eq_1]) ).

cnf(eq_16,plain,
    multiply(C,multiply(multiply(A,x3),double_divide(x3,C))) = A,
    inference(cp,[status(thm)],[eq_15,eq_8]) ).

cnf(eq_17,plain,
    A = multiply(B,multiply(multiply(A,C),double_divide(C,B))),
    eq_16 ).

cnf(eq_18,plain,
    A = inverse(double_divide(inverse(double_divide(double_divide(B,C),inverse(double_divide(B,A)))),C)),
    inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[eq_17,eq_1]),eq_1]),eq_1]) ).

cnf(eq_19,plain,
    double_divide(inverse(double_divide(double_divide(x100,A),double_divide(double_divide(A,B),inverse(double_divide(C,B))))),C) = x100,
    inference(cp,[status(thm)],[eq_6,eq_14]) ).

cnf(eq_20,plain,
    inverse(double_divide(double_divide(double_divide(double_divide(x100,C),inverse(A)),B),x100)) = double_divide(A,inverse(double_divide(B,C))),
    inference(cp,[status(thm)],[eq_14,eq_13]) ).

cnf(eq_21,plain,
    double_divide(double_divide(A,B),inverse(double_divide(C,B))) = double_divide(double_divide(A,x103),inverse(double_divide(C,x103))),
    inference(cp,[status(thm)],[eq_12,eq_12]) ).

cnf(eq_22,plain,
    double_divide(A,inverse(double_divide(B,C))) = inverse(double_divide(double_divide(double_divide(double_divide(x3,C),inverse(A)),B),x3)),
    eq_20 ).

cnf(eq_23,plain,
    A = double_divide(inverse(double_divide(double_divide(A,B),double_divide(double_divide(B,C),inverse(double_divide(x3,C))))),x3),
    eq_19 ).

cnf(eq_24,plain,
    double_divide(double_divide(A,B),inverse(double_divide(C,B))) = double_divide(double_divide(A,x3),inverse(double_divide(C,x3))),
    eq_21 ).

cnf(eq_25,plain,
    double_divide(C,x101) = double_divide(x102,inverse(double_divide(inverse(double_divide(C,inverse(x102))),x101))),
    inference(cp,[status(thm)],[eq_6,eq_22]) ).

cnf(eq_26,plain,
    inverse(double_divide(A,inverse(double_divide(inverse(double_divide(double_divide(A,B),x102)),B)))) = x102,
    inference(cp,[status(thm)],[eq_6,eq_18]) ).

cnf(eq_27,plain,
    inverse(double_divide(inverse(double_divide(double_divide(C,B),inverse(double_divide(C,B)))),x3)) = x3,
    inference(cp,[status(thm)],[eq_24,eq_18]) ).

cnf(eq_28,plain,
    double_divide(A,B) = double_divide(C,inverse(double_divide(inverse(double_divide(A,inverse(C))),B))),
    eq_25 ).

cnf(eq_29,plain,
    A = inverse(double_divide(B,inverse(double_divide(inverse(double_divide(double_divide(B,C),A)),C)))),
    eq_26 ).

cnf(eq_30,plain,
    A = inverse(double_divide(inverse(double_divide(double_divide(B,C),inverse(double_divide(B,C)))),A)),
    eq_27 ).

cnf(eq_31,plain,
    double_divide(x100,inverse(A)) = double_divide(double_divide(A,inverse(double_divide(inverse(x100),C))),C),
    inference(cp,[status(thm)],[eq_14,eq_28]) ).

cnf(eq_32,plain,
    inverse(double_divide(A,inverse(A))) = double_divide(double_divide(x3,C),inverse(double_divide(x3,C))),
    inference(cp,[status(thm)],[eq_23,eq_29]) ).

cnf(eq_33,plain,
    inverse(double_divide(inverse(double_divide(double_divide(double_divide(double_divide(A,B),inverse(double_divide(C,B))),C),A)),x102)) = x102,
    inference(cp,[status(thm)],[eq_6,eq_30]) ).

cnf(eq_34,plain,
    inverse(double_divide(inverse(double_divide(double_divide(inverse(double_divide(double_divide(A,inverse(double_divide(B,C))),B)),C),inverse(A))),x102)) = x102,
    inference(cp,[status(thm)],[eq_14,eq_30]) ).

cnf(eq_35,plain,
    double_divide(A,inverse(B)) = double_divide(double_divide(B,inverse(double_divide(inverse(A),C))),C),
    eq_31 ).

cnf(eq_36,plain,
    A = inverse(double_divide(inverse(double_divide(B,inverse(B))),A)),
    inference(rw,[status(thm)],[eq_34,eq_14]) ).

cnf(eq_37,plain,
    A = inverse(double_divide(double_divide(double_divide(B,C),inverse(double_divide(B,C))),A)),
    inference(rw,[status(thm)],[eq_33,eq_22]) ).

cnf(eq_38,plain,
    double_divide(double_divide(A,B),inverse(double_divide(A,B))) = inverse(double_divide(C,inverse(C))),
    eq_32 ).

cnf(eq_39,plain,
    inverse(double_divide(A,inverse(x103))) = double_divide(inverse(A),x103),
    inference(cp,[status(thm)],[eq_35,eq_7]) ).

cnf(eq_40,plain,
    double_divide(A,inverse(double_divide(inverse(double_divide(double_divide(x3,C),inverse(A))),C))) = x3,
    inference(cp,[status(thm)],[eq_22,eq_37]) ).

cnf(eq_41,plain,
    double_divide(inverse(A),B) = inverse(double_divide(A,inverse(B))),
    eq_39 ).

cnf(eq_42,plain,
    A = double_divide(double_divide(A,B),B),
    inference(rw,[status(thm)],[eq_40,eq_28]) ).

cnf(eq_43,negated_conjecture,
    double_divide(double_divide(A,B),inverse(double_divide(A,B))) != inverse(double_divide(a1,inverse(a1))),
    inference(cp,[status(thm)],[eq_38,eq_3]) ).

cnf(eq_44,plain,
    A = inverse(double_divide(double_divide(inverse(B),B),A)),
    inference(rw,[status(thm)],[eq_36,eq_41]) ).

cnf(eq_45,negated_conjecture,
    double_divide(double_divide(double_divide(inverse(B),B),A),A) != inverse(double_divide(a1,inverse(a1))),
    inference(cp,[status(thm)],[eq_44,eq_43]) ).

cnf(eq_46,negated_conjecture,
    double_divide(inverse(A),A) != double_divide(inverse(a1),a1),
    inference(rw,[status(thm)],[inference(rw,[status(thm)],[eq_45,eq_42]),eq_41]) ).

cnf(eq_47,negated_conjecture,
    double_divide(inverse(A),A) != double_divide(inverse(A),A),
    eq_46 ).

cnf(bot,negated_conjecture,
    $false,
    inference(cn,[status(thm)],[eq_47]) ).

%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.07/0.12  % Problem  : GRP593-1 : TPTP v8.1.0. Released v2.6.0.
% 0.07/0.12  % Command  : run_maedmax %d %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 : Tue Jul 26 04:22:51 EDT 2022
% 0.12/0.33  % CPUTime  : 
% 0.76/0.93  % SZS status Unsatisfiable
% 0.76/0.93  % SZS output start CNFRefutation for /tmp/MaedMax_4734
% See solution above
% 0.76/0.93  
%------------------------------------------------------------------------------