TSTP Solution File: RNG010-2 by iProverMo---2.5-0.1
View Problem
- Process Solution
%------------------------------------------------------------------------------
% File : iProverMo---2.5-0.1
% Problem : RNG010-2 : TPTP v8.1.0. Bugfixed v1.2.1.
% Transfm : none
% Format : tptp:raw
% Command : iprover_modulo %s %d
% Computer : n020.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 : Mon Jul 18 20:30:03 EDT 2022
% Result : Unsatisfiable 0.21s 0.44s
% Output : CNFRefutation 0.21s
% Verified :
% SZS Type : ERROR: Analysing output (Could not find formula named input)
% Comments :
%------------------------------------------------------------------------------
% Axioms transformation by autotheo
% Orienting (remaining) axiom formulas using strategy Equiv(ClausalAll)
% Orienting axioms whose shape is orientable
cnf(associator_skew_symmetry2,axiom,
associator(Z,Y,X) != additive_inverse(associator(X,Y,Z)),
input ).
fof(associator_skew_symmetry2_0,plain,
! [X,Y,Z] :
( associator(Z,Y,X) != additive_inverse(associator(X,Y,Z))
| $false ),
inference(orientation,[status(thm)],[associator_skew_symmetry2]) ).
cnf(associator_skew_symmetry1,axiom,
associator(Y,X,Z) != additive_inverse(associator(X,Y,Z)),
input ).
fof(associator_skew_symmetry1_0,plain,
! [X,Y,Z] :
( associator(Y,X,Z) != additive_inverse(associator(X,Y,Z))
| $false ),
inference(orientation,[status(thm)],[associator_skew_symmetry1]) ).
cnf(middle_law,axiom,
multiply(multiply(Y,X),Y) != multiply(Y,multiply(X,Y)),
input ).
fof(middle_law_0,plain,
! [X,Y] :
( multiply(multiply(Y,X),Y) != multiply(Y,multiply(X,Y))
| $false ),
inference(orientation,[status(thm)],[middle_law]) ).
cnf(associator,axiom,
associator(X,Y,Z) = add(multiply(multiply(X,Y),Z),additive_inverse(multiply(X,multiply(Y,Z)))),
input ).
fof(associator_0,plain,
! [X,Y,Z] :
( associator(X,Y,Z) = add(multiply(multiply(X,Y),Z),additive_inverse(multiply(X,multiply(Y,Z))))
| $false ),
inference(orientation,[status(thm)],[associator]) ).
cnf(associativity_for_addition,axiom,
add(X,add(Y,Z)) = add(add(X,Y),Z),
input ).
fof(associativity_for_addition_0,plain,
! [X,Y,Z] :
( add(X,add(Y,Z)) = add(add(X,Y),Z)
| $false ),
inference(orientation,[status(thm)],[associativity_for_addition]) ).
cnf(commutativity_for_addition,axiom,
add(X,Y) = add(Y,X),
input ).
fof(commutativity_for_addition_0,plain,
! [X,Y] :
( add(X,Y) = add(Y,X)
| $false ),
inference(orientation,[status(thm)],[commutativity_for_addition]) ).
cnf(inverse_additive_identity,axiom,
additive_inverse(additive_identity) = additive_identity,
input ).
fof(inverse_additive_identity_0,plain,
( additive_inverse(additive_identity) = additive_identity
| $false ),
inference(orientation,[status(thm)],[inverse_additive_identity]) ).
cnf(inverse_product2,axiom,
multiply(X,additive_inverse(Y)) = additive_inverse(multiply(X,Y)),
input ).
fof(inverse_product2_0,plain,
! [X,Y] :
( multiply(X,additive_inverse(Y)) = additive_inverse(multiply(X,Y))
| $false ),
inference(orientation,[status(thm)],[inverse_product2]) ).
cnf(inverse_product1,axiom,
multiply(additive_inverse(X),Y) = additive_inverse(multiply(X,Y)),
input ).
fof(inverse_product1_0,plain,
! [X,Y] :
( multiply(additive_inverse(X),Y) = additive_inverse(multiply(X,Y))
| $false ),
inference(orientation,[status(thm)],[inverse_product1]) ).
cnf(left_alternative,axiom,
multiply(multiply(X,X),Y) = multiply(X,multiply(X,Y)),
input ).
fof(left_alternative_0,plain,
! [X,Y] :
( multiply(multiply(X,X),Y) = multiply(X,multiply(X,Y))
| $false ),
inference(orientation,[status(thm)],[left_alternative]) ).
cnf(right_alternative,axiom,
multiply(multiply(X,Y),Y) = multiply(X,multiply(Y,Y)),
input ).
fof(right_alternative_0,plain,
! [X,Y] :
( multiply(multiply(X,Y),Y) = multiply(X,multiply(Y,Y))
| $false ),
inference(orientation,[status(thm)],[right_alternative]) ).
cnf(multiply_over_add2,axiom,
multiply(add(X,Y),Z) = add(multiply(X,Z),multiply(Y,Z)),
input ).
fof(multiply_over_add2_0,plain,
! [X,Y,Z] :
( multiply(add(X,Y),Z) = add(multiply(X,Z),multiply(Y,Z))
| $false ),
inference(orientation,[status(thm)],[multiply_over_add2]) ).
cnf(multiply_over_add1,axiom,
multiply(X,add(Y,Z)) = add(multiply(X,Y),multiply(X,Z)),
input ).
fof(multiply_over_add1_0,plain,
! [X,Y,Z] :
( multiply(X,add(Y,Z)) = add(multiply(X,Y),multiply(X,Z))
| $false ),
inference(orientation,[status(thm)],[multiply_over_add1]) ).
cnf(additive_inverse_additive_inverse,axiom,
additive_inverse(additive_inverse(X)) = X,
input ).
fof(additive_inverse_additive_inverse_0,plain,
! [X] :
( additive_inverse(additive_inverse(X)) = X
| $false ),
inference(orientation,[status(thm)],[additive_inverse_additive_inverse]) ).
cnf(sum_of_inverses,axiom,
additive_inverse(add(X,Y)) = add(additive_inverse(X),additive_inverse(Y)),
input ).
fof(sum_of_inverses_0,plain,
! [X,Y] :
( additive_inverse(add(X,Y)) = add(additive_inverse(X),additive_inverse(Y))
| $false ),
inference(orientation,[status(thm)],[sum_of_inverses]) ).
cnf(add_inverse,axiom,
add(additive_inverse(X),X) = additive_identity,
input ).
fof(add_inverse_0,plain,
! [X] :
( add(additive_inverse(X),X) = additive_identity
| $false ),
inference(orientation,[status(thm)],[add_inverse]) ).
cnf(right_multiplicative_zero,axiom,
multiply(X,additive_identity) = additive_identity,
input ).
fof(right_multiplicative_zero_0,plain,
! [X] :
( multiply(X,additive_identity) = additive_identity
| $false ),
inference(orientation,[status(thm)],[right_multiplicative_zero]) ).
cnf(left_multiplicative_zero,axiom,
multiply(additive_identity,X) = additive_identity,
input ).
fof(left_multiplicative_zero_0,plain,
! [X] :
( multiply(additive_identity,X) = additive_identity
| $false ),
inference(orientation,[status(thm)],[left_multiplicative_zero]) ).
cnf(left_additive_identity,axiom,
add(additive_identity,X) = X,
input ).
fof(left_additive_identity_0,plain,
! [X] :
( add(additive_identity,X) = X
| $false ),
inference(orientation,[status(thm)],[left_additive_identity]) ).
fof(def_lhs_atom1,axiom,
! [X] :
( lhs_atom1(X)
<=> add(additive_identity,X) = X ),
inference(definition,[],]) ).
fof(to_be_clausified_0,plain,
! [X] :
( lhs_atom1(X)
| $false ),
inference(fold_definition,[status(thm)],[left_additive_identity_0,def_lhs_atom1]) ).
fof(def_lhs_atom2,axiom,
! [X] :
( lhs_atom2(X)
<=> multiply(additive_identity,X) = additive_identity ),
inference(definition,[],]) ).
fof(to_be_clausified_1,plain,
! [X] :
( lhs_atom2(X)
| $false ),
inference(fold_definition,[status(thm)],[left_multiplicative_zero_0,def_lhs_atom2]) ).
fof(def_lhs_atom3,axiom,
! [X] :
( lhs_atom3(X)
<=> multiply(X,additive_identity) = additive_identity ),
inference(definition,[],]) ).
fof(to_be_clausified_2,plain,
! [X] :
( lhs_atom3(X)
| $false ),
inference(fold_definition,[status(thm)],[right_multiplicative_zero_0,def_lhs_atom3]) ).
fof(def_lhs_atom4,axiom,
! [X] :
( lhs_atom4(X)
<=> add(additive_inverse(X),X) = additive_identity ),
inference(definition,[],]) ).
fof(to_be_clausified_3,plain,
! [X] :
( lhs_atom4(X)
| $false ),
inference(fold_definition,[status(thm)],[add_inverse_0,def_lhs_atom4]) ).
fof(def_lhs_atom5,axiom,
! [Y,X] :
( lhs_atom5(Y,X)
<=> additive_inverse(add(X,Y)) = add(additive_inverse(X),additive_inverse(Y)) ),
inference(definition,[],]) ).
fof(to_be_clausified_4,plain,
! [X,Y] :
( lhs_atom5(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[sum_of_inverses_0,def_lhs_atom5]) ).
fof(def_lhs_atom6,axiom,
! [X] :
( lhs_atom6(X)
<=> additive_inverse(additive_inverse(X)) = X ),
inference(definition,[],]) ).
fof(to_be_clausified_5,plain,
! [X] :
( lhs_atom6(X)
| $false ),
inference(fold_definition,[status(thm)],[additive_inverse_additive_inverse_0,def_lhs_atom6]) ).
fof(def_lhs_atom7,axiom,
! [Z,Y,X] :
( lhs_atom7(Z,Y,X)
<=> multiply(X,add(Y,Z)) = add(multiply(X,Y),multiply(X,Z)) ),
inference(definition,[],]) ).
fof(to_be_clausified_6,plain,
! [X,Y,Z] :
( lhs_atom7(Z,Y,X)
| $false ),
inference(fold_definition,[status(thm)],[multiply_over_add1_0,def_lhs_atom7]) ).
fof(def_lhs_atom8,axiom,
! [Z,Y,X] :
( lhs_atom8(Z,Y,X)
<=> multiply(add(X,Y),Z) = add(multiply(X,Z),multiply(Y,Z)) ),
inference(definition,[],]) ).
fof(to_be_clausified_7,plain,
! [X,Y,Z] :
( lhs_atom8(Z,Y,X)
| $false ),
inference(fold_definition,[status(thm)],[multiply_over_add2_0,def_lhs_atom8]) ).
fof(def_lhs_atom9,axiom,
! [Y,X] :
( lhs_atom9(Y,X)
<=> multiply(multiply(X,Y),Y) = multiply(X,multiply(Y,Y)) ),
inference(definition,[],]) ).
fof(to_be_clausified_8,plain,
! [X,Y] :
( lhs_atom9(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[right_alternative_0,def_lhs_atom9]) ).
fof(def_lhs_atom10,axiom,
! [Y,X] :
( lhs_atom10(Y,X)
<=> multiply(multiply(X,X),Y) = multiply(X,multiply(X,Y)) ),
inference(definition,[],]) ).
fof(to_be_clausified_9,plain,
! [X,Y] :
( lhs_atom10(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[left_alternative_0,def_lhs_atom10]) ).
fof(def_lhs_atom11,axiom,
! [Y,X] :
( lhs_atom11(Y,X)
<=> multiply(additive_inverse(X),Y) = additive_inverse(multiply(X,Y)) ),
inference(definition,[],]) ).
fof(to_be_clausified_10,plain,
! [X,Y] :
( lhs_atom11(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[inverse_product1_0,def_lhs_atom11]) ).
fof(def_lhs_atom12,axiom,
! [Y,X] :
( lhs_atom12(Y,X)
<=> multiply(X,additive_inverse(Y)) = additive_inverse(multiply(X,Y)) ),
inference(definition,[],]) ).
fof(to_be_clausified_11,plain,
! [X,Y] :
( lhs_atom12(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[inverse_product2_0,def_lhs_atom12]) ).
fof(def_lhs_atom13,axiom,
( lhs_atom13
<=> additive_inverse(additive_identity) = additive_identity ),
inference(definition,[],]) ).
fof(to_be_clausified_12,plain,
( lhs_atom13
| $false ),
inference(fold_definition,[status(thm)],[inverse_additive_identity_0,def_lhs_atom13]) ).
fof(def_lhs_atom14,axiom,
! [Y,X] :
( lhs_atom14(Y,X)
<=> add(X,Y) = add(Y,X) ),
inference(definition,[],]) ).
fof(to_be_clausified_13,plain,
! [X,Y] :
( lhs_atom14(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[commutativity_for_addition_0,def_lhs_atom14]) ).
fof(def_lhs_atom15,axiom,
! [Z,Y,X] :
( lhs_atom15(Z,Y,X)
<=> add(X,add(Y,Z)) = add(add(X,Y),Z) ),
inference(definition,[],]) ).
fof(to_be_clausified_14,plain,
! [X,Y,Z] :
( lhs_atom15(Z,Y,X)
| $false ),
inference(fold_definition,[status(thm)],[associativity_for_addition_0,def_lhs_atom15]) ).
fof(def_lhs_atom16,axiom,
! [Z,Y,X] :
( lhs_atom16(Z,Y,X)
<=> associator(X,Y,Z) = add(multiply(multiply(X,Y),Z),additive_inverse(multiply(X,multiply(Y,Z)))) ),
inference(definition,[],]) ).
fof(to_be_clausified_15,plain,
! [X,Y,Z] :
( lhs_atom16(Z,Y,X)
| $false ),
inference(fold_definition,[status(thm)],[associator_0,def_lhs_atom16]) ).
fof(def_lhs_atom17,axiom,
! [Y,X] :
( lhs_atom17(Y,X)
<=> multiply(multiply(Y,X),Y) != multiply(Y,multiply(X,Y)) ),
inference(definition,[],]) ).
fof(to_be_clausified_16,plain,
! [X,Y] :
( lhs_atom17(Y,X)
| $false ),
inference(fold_definition,[status(thm)],[middle_law_0,def_lhs_atom17]) ).
fof(def_lhs_atom18,axiom,
! [Z,Y,X] :
( lhs_atom18(Z,Y,X)
<=> associator(Y,X,Z) != additive_inverse(associator(X,Y,Z)) ),
inference(definition,[],]) ).
fof(to_be_clausified_17,plain,
! [X,Y,Z] :
( lhs_atom18(Z,Y,X)
| $false ),
inference(fold_definition,[status(thm)],[associator_skew_symmetry1_0,def_lhs_atom18]) ).
fof(def_lhs_atom19,axiom,
! [Z,Y,X] :
( lhs_atom19(Z,Y,X)
<=> associator(Z,Y,X) != additive_inverse(associator(X,Y,Z)) ),
inference(definition,[],]) ).
fof(to_be_clausified_18,plain,
! [X,Y,Z] :
( lhs_atom19(Z,Y,X)
| $false ),
inference(fold_definition,[status(thm)],[associator_skew_symmetry2_0,def_lhs_atom19]) ).
% Start CNF derivation
fof(c_0_0,axiom,
! [X3,X2,X1] :
( lhs_atom19(X3,X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_18) ).
fof(c_0_1,axiom,
! [X3,X2,X1] :
( lhs_atom18(X3,X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_17) ).
fof(c_0_2,axiom,
! [X3,X2,X1] :
( lhs_atom16(X3,X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_15) ).
fof(c_0_3,axiom,
! [X3,X2,X1] :
( lhs_atom15(X3,X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_14) ).
fof(c_0_4,axiom,
! [X3,X2,X1] :
( lhs_atom8(X3,X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_7) ).
fof(c_0_5,axiom,
! [X3,X2,X1] :
( lhs_atom7(X3,X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_6) ).
fof(c_0_6,axiom,
! [X2,X1] :
( lhs_atom17(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_16) ).
fof(c_0_7,axiom,
! [X2,X1] :
( lhs_atom14(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_13) ).
fof(c_0_8,axiom,
! [X2,X1] :
( lhs_atom12(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_11) ).
fof(c_0_9,axiom,
! [X2,X1] :
( lhs_atom11(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_10) ).
fof(c_0_10,axiom,
! [X2,X1] :
( lhs_atom10(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_9) ).
fof(c_0_11,axiom,
! [X2,X1] :
( lhs_atom9(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_8) ).
fof(c_0_12,axiom,
! [X2,X1] :
( lhs_atom5(X2,X1)
| ~ $true ),
file('<stdin>',to_be_clausified_4) ).
fof(c_0_13,axiom,
! [X1] :
( lhs_atom6(X1)
| ~ $true ),
file('<stdin>',to_be_clausified_5) ).
fof(c_0_14,axiom,
! [X1] :
( lhs_atom4(X1)
| ~ $true ),
file('<stdin>',to_be_clausified_3) ).
fof(c_0_15,axiom,
! [X1] :
( lhs_atom3(X1)
| ~ $true ),
file('<stdin>',to_be_clausified_2) ).
fof(c_0_16,axiom,
! [X1] :
( lhs_atom2(X1)
| ~ $true ),
file('<stdin>',to_be_clausified_1) ).
fof(c_0_17,axiom,
! [X1] :
( lhs_atom1(X1)
| ~ $true ),
file('<stdin>',to_be_clausified_0) ).
fof(c_0_18,axiom,
( lhs_atom13
| ~ $true ),
file('<stdin>',to_be_clausified_12) ).
fof(c_0_19,plain,
! [X3,X2,X1] : lhs_atom19(X3,X2,X1),
inference(fof_simplification,[status(thm)],[c_0_0]) ).
fof(c_0_20,plain,
! [X3,X2,X1] : lhs_atom18(X3,X2,X1),
inference(fof_simplification,[status(thm)],[c_0_1]) ).
fof(c_0_21,plain,
! [X3,X2,X1] : lhs_atom16(X3,X2,X1),
inference(fof_simplification,[status(thm)],[c_0_2]) ).
fof(c_0_22,plain,
! [X3,X2,X1] : lhs_atom15(X3,X2,X1),
inference(fof_simplification,[status(thm)],[c_0_3]) ).
fof(c_0_23,plain,
! [X3,X2,X1] : lhs_atom8(X3,X2,X1),
inference(fof_simplification,[status(thm)],[c_0_4]) ).
fof(c_0_24,plain,
! [X3,X2,X1] : lhs_atom7(X3,X2,X1),
inference(fof_simplification,[status(thm)],[c_0_5]) ).
fof(c_0_25,plain,
! [X2,X1] : lhs_atom17(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_6]) ).
fof(c_0_26,plain,
! [X2,X1] : lhs_atom14(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_7]) ).
fof(c_0_27,plain,
! [X2,X1] : lhs_atom12(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_8]) ).
fof(c_0_28,plain,
! [X2,X1] : lhs_atom11(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_9]) ).
fof(c_0_29,plain,
! [X2,X1] : lhs_atom10(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_10]) ).
fof(c_0_30,plain,
! [X2,X1] : lhs_atom9(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_11]) ).
fof(c_0_31,plain,
! [X2,X1] : lhs_atom5(X2,X1),
inference(fof_simplification,[status(thm)],[c_0_12]) ).
fof(c_0_32,plain,
! [X1] : lhs_atom6(X1),
inference(fof_simplification,[status(thm)],[c_0_13]) ).
fof(c_0_33,plain,
! [X1] : lhs_atom4(X1),
inference(fof_simplification,[status(thm)],[c_0_14]) ).
fof(c_0_34,plain,
! [X1] : lhs_atom3(X1),
inference(fof_simplification,[status(thm)],[c_0_15]) ).
fof(c_0_35,plain,
! [X1] : lhs_atom2(X1),
inference(fof_simplification,[status(thm)],[c_0_16]) ).
fof(c_0_36,plain,
! [X1] : lhs_atom1(X1),
inference(fof_simplification,[status(thm)],[c_0_17]) ).
fof(c_0_37,plain,
lhs_atom13,
inference(fof_simplification,[status(thm)],[c_0_18]) ).
fof(c_0_38,plain,
! [X4,X5,X6] : lhs_atom19(X4,X5,X6),
inference(variable_rename,[status(thm)],[c_0_19]) ).
fof(c_0_39,plain,
! [X4,X5,X6] : lhs_atom18(X4,X5,X6),
inference(variable_rename,[status(thm)],[c_0_20]) ).
fof(c_0_40,plain,
! [X4,X5,X6] : lhs_atom16(X4,X5,X6),
inference(variable_rename,[status(thm)],[c_0_21]) ).
fof(c_0_41,plain,
! [X4,X5,X6] : lhs_atom15(X4,X5,X6),
inference(variable_rename,[status(thm)],[c_0_22]) ).
fof(c_0_42,plain,
! [X4,X5,X6] : lhs_atom8(X4,X5,X6),
inference(variable_rename,[status(thm)],[c_0_23]) ).
fof(c_0_43,plain,
! [X4,X5,X6] : lhs_atom7(X4,X5,X6),
inference(variable_rename,[status(thm)],[c_0_24]) ).
fof(c_0_44,plain,
! [X3,X4] : lhs_atom17(X3,X4),
inference(variable_rename,[status(thm)],[c_0_25]) ).
fof(c_0_45,plain,
! [X3,X4] : lhs_atom14(X3,X4),
inference(variable_rename,[status(thm)],[c_0_26]) ).
fof(c_0_46,plain,
! [X3,X4] : lhs_atom12(X3,X4),
inference(variable_rename,[status(thm)],[c_0_27]) ).
fof(c_0_47,plain,
! [X3,X4] : lhs_atom11(X3,X4),
inference(variable_rename,[status(thm)],[c_0_28]) ).
fof(c_0_48,plain,
! [X3,X4] : lhs_atom10(X3,X4),
inference(variable_rename,[status(thm)],[c_0_29]) ).
fof(c_0_49,plain,
! [X3,X4] : lhs_atom9(X3,X4),
inference(variable_rename,[status(thm)],[c_0_30]) ).
fof(c_0_50,plain,
! [X3,X4] : lhs_atom5(X3,X4),
inference(variable_rename,[status(thm)],[c_0_31]) ).
fof(c_0_51,plain,
! [X2] : lhs_atom6(X2),
inference(variable_rename,[status(thm)],[c_0_32]) ).
fof(c_0_52,plain,
! [X2] : lhs_atom4(X2),
inference(variable_rename,[status(thm)],[c_0_33]) ).
fof(c_0_53,plain,
! [X2] : lhs_atom3(X2),
inference(variable_rename,[status(thm)],[c_0_34]) ).
fof(c_0_54,plain,
! [X2] : lhs_atom2(X2),
inference(variable_rename,[status(thm)],[c_0_35]) ).
fof(c_0_55,plain,
! [X2] : lhs_atom1(X2),
inference(variable_rename,[status(thm)],[c_0_36]) ).
fof(c_0_56,plain,
lhs_atom13,
c_0_37 ).
cnf(c_0_57,plain,
lhs_atom19(X1,X2,X3),
inference(split_conjunct,[status(thm)],[c_0_38]) ).
cnf(c_0_58,plain,
lhs_atom18(X1,X2,X3),
inference(split_conjunct,[status(thm)],[c_0_39]) ).
cnf(c_0_59,plain,
lhs_atom16(X1,X2,X3),
inference(split_conjunct,[status(thm)],[c_0_40]) ).
cnf(c_0_60,plain,
lhs_atom15(X1,X2,X3),
inference(split_conjunct,[status(thm)],[c_0_41]) ).
cnf(c_0_61,plain,
lhs_atom8(X1,X2,X3),
inference(split_conjunct,[status(thm)],[c_0_42]) ).
cnf(c_0_62,plain,
lhs_atom7(X1,X2,X3),
inference(split_conjunct,[status(thm)],[c_0_43]) ).
cnf(c_0_63,plain,
lhs_atom17(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_44]) ).
cnf(c_0_64,plain,
lhs_atom14(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_45]) ).
cnf(c_0_65,plain,
lhs_atom12(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_46]) ).
cnf(c_0_66,plain,
lhs_atom11(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_47]) ).
cnf(c_0_67,plain,
lhs_atom10(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_48]) ).
cnf(c_0_68,plain,
lhs_atom9(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_49]) ).
cnf(c_0_69,plain,
lhs_atom5(X1,X2),
inference(split_conjunct,[status(thm)],[c_0_50]) ).
cnf(c_0_70,plain,
lhs_atom6(X1),
inference(split_conjunct,[status(thm)],[c_0_51]) ).
cnf(c_0_71,plain,
lhs_atom4(X1),
inference(split_conjunct,[status(thm)],[c_0_52]) ).
cnf(c_0_72,plain,
lhs_atom3(X1),
inference(split_conjunct,[status(thm)],[c_0_53]) ).
cnf(c_0_73,plain,
lhs_atom2(X1),
inference(split_conjunct,[status(thm)],[c_0_54]) ).
cnf(c_0_74,plain,
lhs_atom1(X1),
inference(split_conjunct,[status(thm)],[c_0_55]) ).
cnf(c_0_75,plain,
lhs_atom13,
inference(split_conjunct,[status(thm)],[c_0_56]) ).
cnf(c_0_76,plain,
lhs_atom19(X1,X2,X3),
c_0_57,
[final] ).
cnf(c_0_77,plain,
lhs_atom18(X1,X2,X3),
c_0_58,
[final] ).
cnf(c_0_78,plain,
lhs_atom16(X1,X2,X3),
c_0_59,
[final] ).
cnf(c_0_79,plain,
lhs_atom15(X1,X2,X3),
c_0_60,
[final] ).
cnf(c_0_80,plain,
lhs_atom8(X1,X2,X3),
c_0_61,
[final] ).
cnf(c_0_81,plain,
lhs_atom7(X1,X2,X3),
c_0_62,
[final] ).
cnf(c_0_82,plain,
lhs_atom17(X1,X2),
c_0_63,
[final] ).
cnf(c_0_83,plain,
lhs_atom14(X1,X2),
c_0_64,
[final] ).
cnf(c_0_84,plain,
lhs_atom12(X1,X2),
c_0_65,
[final] ).
cnf(c_0_85,plain,
lhs_atom11(X1,X2),
c_0_66,
[final] ).
cnf(c_0_86,plain,
lhs_atom10(X1,X2),
c_0_67,
[final] ).
cnf(c_0_87,plain,
lhs_atom9(X1,X2),
c_0_68,
[final] ).
cnf(c_0_88,plain,
lhs_atom5(X1,X2),
c_0_69,
[final] ).
cnf(c_0_89,plain,
lhs_atom6(X1),
c_0_70,
[final] ).
cnf(c_0_90,plain,
lhs_atom4(X1),
c_0_71,
[final] ).
cnf(c_0_91,plain,
lhs_atom3(X1),
c_0_72,
[final] ).
cnf(c_0_92,plain,
lhs_atom2(X1),
c_0_73,
[final] ).
cnf(c_0_93,plain,
lhs_atom1(X1),
c_0_74,
[final] ).
cnf(c_0_94,plain,
lhs_atom13,
c_0_75,
[final] ).
% End CNF derivation
cnf(c_0_76_0,axiom,
associator(X1,X2,X3) != additive_inverse(associator(X3,X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_76,def_lhs_atom19]) ).
cnf(c_0_77_0,axiom,
associator(X2,X3,X1) != additive_inverse(associator(X3,X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_77,def_lhs_atom18]) ).
cnf(c_0_78_0,axiom,
associator(X3,X2,X1) = add(multiply(multiply(X3,X2),X1),additive_inverse(multiply(X3,multiply(X2,X1)))),
inference(unfold_definition,[status(thm)],[c_0_78,def_lhs_atom16]) ).
cnf(c_0_79_0,axiom,
add(X3,add(X2,X1)) = add(add(X3,X2),X1),
inference(unfold_definition,[status(thm)],[c_0_79,def_lhs_atom15]) ).
cnf(c_0_80_0,axiom,
multiply(add(X3,X2),X1) = add(multiply(X3,X1),multiply(X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_80,def_lhs_atom8]) ).
cnf(c_0_81_0,axiom,
multiply(X3,add(X2,X1)) = add(multiply(X3,X2),multiply(X3,X1)),
inference(unfold_definition,[status(thm)],[c_0_81,def_lhs_atom7]) ).
cnf(c_0_82_0,axiom,
multiply(multiply(X1,X2),X1) != multiply(X1,multiply(X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_82,def_lhs_atom17]) ).
cnf(c_0_83_0,axiom,
add(X2,X1) = add(X1,X2),
inference(unfold_definition,[status(thm)],[c_0_83,def_lhs_atom14]) ).
cnf(c_0_84_0,axiom,
multiply(X2,additive_inverse(X1)) = additive_inverse(multiply(X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_84,def_lhs_atom12]) ).
cnf(c_0_85_0,axiom,
multiply(additive_inverse(X2),X1) = additive_inverse(multiply(X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_85,def_lhs_atom11]) ).
cnf(c_0_86_0,axiom,
multiply(multiply(X2,X2),X1) = multiply(X2,multiply(X2,X1)),
inference(unfold_definition,[status(thm)],[c_0_86,def_lhs_atom10]) ).
cnf(c_0_87_0,axiom,
multiply(multiply(X2,X1),X1) = multiply(X2,multiply(X1,X1)),
inference(unfold_definition,[status(thm)],[c_0_87,def_lhs_atom9]) ).
cnf(c_0_88_0,axiom,
additive_inverse(add(X2,X1)) = add(additive_inverse(X2),additive_inverse(X1)),
inference(unfold_definition,[status(thm)],[c_0_88,def_lhs_atom5]) ).
cnf(c_0_89_0,axiom,
additive_inverse(additive_inverse(X1)) = X1,
inference(unfold_definition,[status(thm)],[c_0_89,def_lhs_atom6]) ).
cnf(c_0_90_0,axiom,
add(additive_inverse(X1),X1) = additive_identity,
inference(unfold_definition,[status(thm)],[c_0_90,def_lhs_atom4]) ).
cnf(c_0_91_0,axiom,
multiply(X1,additive_identity) = additive_identity,
inference(unfold_definition,[status(thm)],[c_0_91,def_lhs_atom3]) ).
cnf(c_0_92_0,axiom,
multiply(additive_identity,X1) = additive_identity,
inference(unfold_definition,[status(thm)],[c_0_92,def_lhs_atom2]) ).
cnf(c_0_93_0,axiom,
add(additive_identity,X1) = X1,
inference(unfold_definition,[status(thm)],[c_0_93,def_lhs_atom1]) ).
cnf(c_0_94_0,axiom,
additive_inverse(additive_identity) = additive_identity,
inference(unfold_definition,[status(thm)],[c_0_94,def_lhs_atom13]) ).
% Orienting (remaining) axiom formulas using strategy ClausalAll
% CNF of (remaining) axioms:
% Start CNF derivation
fof(c_0_0_001,axiom,
! [X1,X2,X3] :
( add(X3,X1) != add(X2,X1)
| X3 = X2 ),
file('<stdin>',left_cancellation_for_addition) ).
fof(c_0_1_002,axiom,
! [X1,X2,X3] :
( add(X1,X3) != add(X1,X2)
| X3 = X2 ),
file('<stdin>',right_cancellation_for_addition) ).
fof(c_0_2_003,axiom,
! [X1,X2,X3] :
( add(X3,X1) != add(X2,X1)
| X3 = X2 ),
c_0_0 ).
fof(c_0_3_004,axiom,
! [X1,X2,X3] :
( add(X1,X3) != add(X1,X2)
| X3 = X2 ),
c_0_1 ).
fof(c_0_4_005,plain,
! [X4,X5,X6] :
( add(X6,X4) != add(X5,X4)
| X6 = X5 ),
inference(variable_rename,[status(thm)],[c_0_2]) ).
fof(c_0_5_006,plain,
! [X4,X5,X6] :
( add(X4,X6) != add(X4,X5)
| X6 = X5 ),
inference(variable_rename,[status(thm)],[c_0_3]) ).
cnf(c_0_6_007,plain,
( X1 = X2
| add(X1,X3) != add(X2,X3) ),
inference(split_conjunct,[status(thm)],[c_0_4]) ).
cnf(c_0_7_008,plain,
( X1 = X2
| add(X3,X1) != add(X3,X2) ),
inference(split_conjunct,[status(thm)],[c_0_5]) ).
cnf(c_0_8_009,plain,
( X1 = X2
| add(X1,X3) != add(X2,X3) ),
c_0_6,
[final] ).
cnf(c_0_9_010,plain,
( X1 = X2
| add(X3,X1) != add(X3,X2) ),
c_0_7,
[final] ).
% End CNF derivation
% Generating one_way clauses for all literals in the CNF.
cnf(c_0_8_0,axiom,
( X1 = X2
| add(X1,X3) != add(X2,X3) ),
inference(literals_permutation,[status(thm)],[c_0_8]) ).
cnf(c_0_8_1,axiom,
( add(X1,X3) != add(X2,X3)
| X1 = X2 ),
inference(literals_permutation,[status(thm)],[c_0_8]) ).
cnf(c_0_9_0,axiom,
( X1 = X2
| add(X3,X1) != add(X3,X2) ),
inference(literals_permutation,[status(thm)],[c_0_9]) ).
cnf(c_0_9_1,axiom,
( add(X3,X1) != add(X3,X2)
| X1 = X2 ),
inference(literals_permutation,[status(thm)],[c_0_9]) ).
% CNF of non-axioms
% Start CNF derivation
fof(c_0_0_011,negated_conjecture,
associator(multiply(cx,cx),cy,cz) != add(multiply(associator(cx,cy,cz),cx),multiply(cx,associator(cx,cy,cz))),
file('<stdin>',prove_skew_symmetry) ).
fof(c_0_1_012,hypothesis,
! [X1,X2,X3] : multiply(multiply(X3,multiply(X2,X3)),X1) = multiply(X3,multiply(X2,multiply(X3,X1))),
file('<stdin>',left_moufang) ).
fof(c_0_2_013,hypothesis,
! [X1,X2,X3] : multiply(X1,multiply(X3,multiply(X2,X3))) = multiply(multiply(multiply(X1,X3),X2),X3),
file('<stdin>',right_moufang) ).
fof(c_0_3_014,negated_conjecture,
associator(multiply(cx,cx),cy,cz) != add(multiply(associator(cx,cy,cz),cx),multiply(cx,associator(cx,cy,cz))),
c_0_0 ).
fof(c_0_4_015,hypothesis,
! [X1,X2,X3] : multiply(multiply(X3,multiply(X2,X3)),X1) = multiply(X3,multiply(X2,multiply(X3,X1))),
c_0_1 ).
fof(c_0_5_016,hypothesis,
! [X1,X2,X3] : multiply(X1,multiply(X3,multiply(X2,X3))) = multiply(multiply(multiply(X1,X3),X2),X3),
c_0_2 ).
fof(c_0_6_017,negated_conjecture,
associator(multiply(cx,cx),cy,cz) != add(multiply(associator(cx,cy,cz),cx),multiply(cx,associator(cx,cy,cz))),
c_0_3 ).
fof(c_0_7_018,hypothesis,
! [X4,X5,X6] : multiply(multiply(X6,multiply(X5,X6)),X4) = multiply(X6,multiply(X5,multiply(X6,X4))),
inference(variable_rename,[status(thm)],[c_0_4]) ).
fof(c_0_8_019,hypothesis,
! [X4,X5,X6] : multiply(X4,multiply(X6,multiply(X5,X6))) = multiply(multiply(multiply(X4,X6),X5),X6),
inference(variable_rename,[status(thm)],[c_0_5]) ).
cnf(c_0_9_020,negated_conjecture,
associator(multiply(cx,cx),cy,cz) != add(multiply(associator(cx,cy,cz),cx),multiply(cx,associator(cx,cy,cz))),
inference(split_conjunct,[status(thm)],[c_0_6]) ).
cnf(c_0_10_021,hypothesis,
multiply(multiply(X1,multiply(X2,X1)),X3) = multiply(X1,multiply(X2,multiply(X1,X3))),
inference(split_conjunct,[status(thm)],[c_0_7]) ).
cnf(c_0_11_022,hypothesis,
multiply(X1,multiply(X2,multiply(X3,X2))) = multiply(multiply(multiply(X1,X2),X3),X2),
inference(split_conjunct,[status(thm)],[c_0_8]) ).
cnf(c_0_12_023,negated_conjecture,
add(multiply(associator(cx,cy,cz),cx),multiply(cx,associator(cx,cy,cz))) != associator(multiply(cx,cx),cy,cz),
c_0_9,
[final] ).
cnf(c_0_13_024,hypothesis,
multiply(multiply(X1,multiply(X2,X1)),X3) = multiply(X1,multiply(X2,multiply(X1,X3))),
c_0_10,
[final] ).
cnf(c_0_14_025,hypothesis,
multiply(multiply(multiply(X1,X2),X3),X2) = multiply(X1,multiply(X2,multiply(X3,X2))),
c_0_11,
[final] ).
% End CNF derivation
%-------------------------------------------------------------
% Proof by iprover
cnf(c_12,plain,
multiply(multiply(X0,X0),X1) = multiply(X0,multiply(X0,X1)),
file('/export/starexec/sandbox2/tmp/iprover_modulo_b318f8.p',c_0_86_0) ).
cnf(c_37,plain,
multiply(multiply(additive_identity,additive_identity),additive_identity) = multiply(additive_identity,multiply(additive_identity,additive_identity)),
inference(instantiation,[status(thm)],[c_12]) ).
cnf(c_16,plain,
multiply(multiply(X0,X1),X0) != multiply(X0,multiply(X1,X0)),
file('/export/starexec/sandbox2/tmp/iprover_modulo_b318f8.p',c_0_82_0) ).
cnf(c_33,plain,
multiply(multiply(additive_identity,additive_identity),additive_identity) != multiply(additive_identity,multiply(additive_identity,additive_identity)),
inference(instantiation,[status(thm)],[c_16]) ).
cnf(contradiction,plain,
$false,
inference(minisat,[status(thm)],[c_37,c_33]) ).
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.04/0.12 % Problem : RNG010-2 : TPTP v8.1.0. Bugfixed v1.2.1.
% 0.04/0.13 % Command : iprover_modulo %s %d
% 0.13/0.34 % Computer : n020.cluster.edu
% 0.13/0.34 % Model : x86_64 x86_64
% 0.13/0.34 % CPU : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.13/0.34 % Memory : 8042.1875MB
% 0.13/0.34 % OS : Linux 3.10.0-693.el7.x86_64
% 0.13/0.34 % CPULimit : 300
% 0.13/0.34 % WCLimit : 600
% 0.13/0.34 % DateTime : Mon May 30 07:07:54 EDT 2022
% 0.13/0.34 % CPUTime :
% 0.13/0.35 % Running in mono-core mode
% 0.21/0.41 % Orienting using strategy Equiv(ClausalAll)
% 0.21/0.41 % Orientation found
% 0.21/0.41 % Executing iprover_moduloopt --modulo true --schedule none --sub_typing false --res_to_prop_solver none --res_prop_simpl_given false --res_lit_sel kbo_max --large_theory_mode false --res_time_limit 1000 --res_orphan_elimination false --prep_sem_filter none --prep_unflatten false --comb_res_mult 1000 --comb_inst_mult 300 --clausifier .//eprover --clausifier_options "--tstp-format " --proof_out_file /export/starexec/sandbox2/tmp/iprover_proof_bbe870.s --tptp_safe_out true --time_out_real 150 /export/starexec/sandbox2/tmp/iprover_modulo_b318f8.p | tee /export/starexec/sandbox2/tmp/iprover_modulo_out_49d413 | grep -v "SZS"
% 0.21/0.43
% 0.21/0.43 %---------------- iProver v2.5 (CASC-J8 2016) ----------------%
% 0.21/0.43
% 0.21/0.43 %
% 0.21/0.43 % ------ iProver source info
% 0.21/0.43
% 0.21/0.43 % git: sha1: 57accf6c58032223c7708532cf852a99fa48c1b3
% 0.21/0.43 % git: non_committed_changes: true
% 0.21/0.43 % git: last_make_outside_of_git: true
% 0.21/0.43
% 0.21/0.43 %
% 0.21/0.43 % ------ Input Options
% 0.21/0.43
% 0.21/0.43 % --out_options all
% 0.21/0.43 % --tptp_safe_out true
% 0.21/0.43 % --problem_path ""
% 0.21/0.43 % --include_path ""
% 0.21/0.43 % --clausifier .//eprover
% 0.21/0.43 % --clausifier_options --tstp-format
% 0.21/0.43 % --stdin false
% 0.21/0.43 % --dbg_backtrace false
% 0.21/0.43 % --dbg_dump_prop_clauses false
% 0.21/0.43 % --dbg_dump_prop_clauses_file -
% 0.21/0.43 % --dbg_out_stat false
% 0.21/0.43
% 0.21/0.43 % ------ General Options
% 0.21/0.43
% 0.21/0.43 % --fof false
% 0.21/0.43 % --time_out_real 150.
% 0.21/0.43 % --time_out_prep_mult 0.2
% 0.21/0.43 % --time_out_virtual -1.
% 0.21/0.43 % --schedule none
% 0.21/0.43 % --ground_splitting input
% 0.21/0.43 % --splitting_nvd 16
% 0.21/0.43 % --non_eq_to_eq false
% 0.21/0.43 % --prep_gs_sim true
% 0.21/0.43 % --prep_unflatten false
% 0.21/0.43 % --prep_res_sim true
% 0.21/0.43 % --prep_upred true
% 0.21/0.43 % --res_sim_input true
% 0.21/0.43 % --clause_weak_htbl true
% 0.21/0.43 % --gc_record_bc_elim false
% 0.21/0.43 % --symbol_type_check false
% 0.21/0.43 % --clausify_out false
% 0.21/0.43 % --large_theory_mode false
% 0.21/0.43 % --prep_sem_filter none
% 0.21/0.43 % --prep_sem_filter_out false
% 0.21/0.43 % --preprocessed_out false
% 0.21/0.43 % --sub_typing false
% 0.21/0.43 % --brand_transform false
% 0.21/0.43 % --pure_diseq_elim true
% 0.21/0.43 % --min_unsat_core false
% 0.21/0.43 % --pred_elim true
% 0.21/0.43 % --add_important_lit false
% 0.21/0.43 % --soft_assumptions false
% 0.21/0.43 % --reset_solvers false
% 0.21/0.43 % --bc_imp_inh []
% 0.21/0.43 % --conj_cone_tolerance 1.5
% 0.21/0.43 % --prolific_symb_bound 500
% 0.21/0.43 % --lt_threshold 2000
% 0.21/0.43
% 0.21/0.43 % ------ SAT Options
% 0.21/0.43
% 0.21/0.43 % --sat_mode false
% 0.21/0.43 % --sat_fm_restart_options ""
% 0.21/0.43 % --sat_gr_def false
% 0.21/0.43 % --sat_epr_types true
% 0.21/0.43 % --sat_non_cyclic_types false
% 0.21/0.43 % --sat_finite_models false
% 0.21/0.43 % --sat_fm_lemmas false
% 0.21/0.43 % --sat_fm_prep false
% 0.21/0.43 % --sat_fm_uc_incr true
% 0.21/0.43 % --sat_out_model small
% 0.21/0.43 % --sat_out_clauses false
% 0.21/0.43
% 0.21/0.43 % ------ QBF Options
% 0.21/0.43
% 0.21/0.43 % --qbf_mode false
% 0.21/0.43 % --qbf_elim_univ true
% 0.21/0.43 % --qbf_sk_in true
% 0.21/0.43 % --qbf_pred_elim true
% 0.21/0.43 % --qbf_split 32
% 0.21/0.43
% 0.21/0.43 % ------ BMC1 Options
% 0.21/0.43
% 0.21/0.43 % --bmc1_incremental false
% 0.21/0.43 % --bmc1_axioms reachable_all
% 0.21/0.43 % --bmc1_min_bound 0
% 0.21/0.43 % --bmc1_max_bound -1
% 0.21/0.43 % --bmc1_max_bound_default -1
% 0.21/0.43 % --bmc1_symbol_reachability true
% 0.21/0.43 % --bmc1_property_lemmas false
% 0.21/0.43 % --bmc1_k_induction false
% 0.21/0.43 % --bmc1_non_equiv_states false
% 0.21/0.43 % --bmc1_deadlock false
% 0.21/0.43 % --bmc1_ucm false
% 0.21/0.43 % --bmc1_add_unsat_core none
% 0.21/0.43 % --bmc1_unsat_core_children false
% 0.21/0.43 % --bmc1_unsat_core_extrapolate_axioms false
% 0.21/0.43 % --bmc1_out_stat full
% 0.21/0.43 % --bmc1_ground_init false
% 0.21/0.43 % --bmc1_pre_inst_next_state false
% 0.21/0.43 % --bmc1_pre_inst_state false
% 0.21/0.43 % --bmc1_pre_inst_reach_state false
% 0.21/0.43 % --bmc1_out_unsat_core false
% 0.21/0.43 % --bmc1_aig_witness_out false
% 0.21/0.43 % --bmc1_verbose false
% 0.21/0.43 % --bmc1_dump_clauses_tptp false
% 0.21/0.44 % --bmc1_dump_unsat_core_tptp false
% 0.21/0.44 % --bmc1_dump_file -
% 0.21/0.44 % --bmc1_ucm_expand_uc_limit 128
% 0.21/0.44 % --bmc1_ucm_n_expand_iterations 6
% 0.21/0.44 % --bmc1_ucm_extend_mode 1
% 0.21/0.44 % --bmc1_ucm_init_mode 2
% 0.21/0.44 % --bmc1_ucm_cone_mode none
% 0.21/0.44 % --bmc1_ucm_reduced_relation_type 0
% 0.21/0.44 % --bmc1_ucm_relax_model 4
% 0.21/0.44 % --bmc1_ucm_full_tr_after_sat true
% 0.21/0.44 % --bmc1_ucm_expand_neg_assumptions false
% 0.21/0.44 % --bmc1_ucm_layered_model none
% 0.21/0.44 % --bmc1_ucm_max_lemma_size 10
% 0.21/0.44
% 0.21/0.44 % ------ AIG Options
% 0.21/0.44
% 0.21/0.44 % --aig_mode false
% 0.21/0.44
% 0.21/0.44 % ------ Instantiation Options
% 0.21/0.44
% 0.21/0.44 % --instantiation_flag true
% 0.21/0.44 % --inst_lit_sel [+prop;+sign;+ground;-num_var;-num_symb]
% 0.21/0.44 % --inst_solver_per_active 750
% 0.21/0.44 % --inst_solver_calls_frac 0.5
% 0.21/0.44 % --inst_passive_queue_type priority_queues
% 0.21/0.44 % --inst_passive_queues [[-conj_dist;+conj_symb;-num_var];[+age;-num_symb]]
% 0.21/0.44 % --inst_passive_queues_freq [25;2]
% 0.21/0.44 % --inst_dismatching true
% 0.21/0.44 % --inst_eager_unprocessed_to_passive true
% 0.21/0.44 % --inst_prop_sim_given true
% 0.21/0.44 % --inst_prop_sim_new false
% 0.21/0.44 % --inst_orphan_elimination true
% 0.21/0.44 % --inst_learning_loop_flag true
% 0.21/0.44 % --inst_learning_start 3000
% 0.21/0.44 % --inst_learning_factor 2
% 0.21/0.44 % --inst_start_prop_sim_after_learn 3
% 0.21/0.44 % --inst_sel_renew solver
% 0.21/0.44 % --inst_lit_activity_flag true
% 0.21/0.44 % --inst_out_proof true
% 0.21/0.44
% 0.21/0.44 % ------ Resolution Options
% 0.21/0.44
% 0.21/0.44 % --resolution_flag true
% 0.21/0.44 % --res_lit_sel kbo_max
% 0.21/0.44 % --res_to_prop_solver none
% 0.21/0.44 % --res_prop_simpl_new false
% 0.21/0.44 % --res_prop_simpl_given false
% 0.21/0.44 % --res_passive_queue_type priority_queues
% 0.21/0.44 % --res_passive_queues [[-conj_dist;+conj_symb;-num_symb];[+age;-num_symb]]
% 0.21/0.44 % --res_passive_queues_freq [15;5]
% 0.21/0.44 % --res_forward_subs full
% 0.21/0.44 % --res_backward_subs full
% 0.21/0.44 % --res_forward_subs_resolution true
% 0.21/0.44 % --res_backward_subs_resolution true
% 0.21/0.44 % --res_orphan_elimination false
% 0.21/0.44 % --res_time_limit 1000.
% 0.21/0.44 % --res_out_proof true
% 0.21/0.44 % --proof_out_file /export/starexec/sandbox2/tmp/iprover_proof_bbe870.s
% 0.21/0.44 % --modulo true
% 0.21/0.44
% 0.21/0.44 % ------ Combination Options
% 0.21/0.44
% 0.21/0.44 % --comb_res_mult 1000
% 0.21/0.44 % --comb_inst_mult 300
% 0.21/0.44 % ------
% 0.21/0.44
% 0.21/0.44 % ------ Parsing...% successful
% 0.21/0.44
% 0.21/0.44 %
% 0.21/0.44
% 0.21/0.44
% 0.21/0.44 % ------ Statistics
% 0.21/0.44
% 0.21/0.44 % ------ General
% 0.21/0.44
% 0.21/0.44 % num_of_input_clauses: 26
% 0.21/0.44 % num_of_input_neg_conjectures: 1
% 0.21/0.44 % num_of_splits: 0
% 0.21/0.44 % num_of_split_atoms: 0
% 0.21/0.44 % num_of_sem_filtered_clauses: 0
% 0.21/0.44 % num_of_subtypes: 0
% 0.21/0.44 % monotx_restored_types: 0
% 0.21/0.44 % sat_num_of_epr_types: 0
% 0.21/0.44 % sat_num_of_non_cyclic_types: 0
% 0.21/0.44 % sat_guarded_non_collapsed_types: 0
% 0.21/0.44 % is_epr: 0
% 0.21/0.44 % is_horn: 0
% 0.21/0.44 % has_eq: 0
% 0.21/0.44 % num_pure_diseq_elim: 0
% 0.21/0.44 % simp_replaced_by: 0
% 0.21/0.44 % res_preprocessed: 0
% 0.21/0.44 % prep_upred: 0
% 0.21/0.44 % prep_unflattend: 0
% 0.21/0.44 % pred_elim_cands: 0
% 0.21/0.44 % pred_elim: 0
% 0.21/0.44 % pred_elim_cl: 0
% 0.21/0.44 % pred_elim_cycles: 0
% 0.21/0.44 % forced_gc_time: 0
% 0.21/0.44 % gc_basic_clause_elim: 0
% 0.21/0.44 % parsing_time: 0.001
% 0.21/0.44 % sem_filter_time: 0.
% 0.21/0.44 % pred_elim_time: 0.
% 0.21/0.44 % out_proof_time: 0.
% 0.21/0.44 % monotx_time: 0.
% 0.21/0.44 % subtype_inf_time: 0.
% 0.21/0.44 % unif_index_cands_time: 0.
% 0.21/0.44 % unif_index_add_time: 0.
% 0.21/0.44 % total_time: 0.02
% 0.21/0.44 % num_of_symbols: 33
% 0.21/0.44 % num_of_terms: 176
% 0.21/0.44
% 0.21/0.44 % ------ Propositional Solver
% 0.21/0.44
% 0.21/0.44 % prop_solver_calls: 0
% 0.21/0.44 % prop_fast_solver_calls: 0
% 0.21/0.44 % prop_num_of_clauses: 25
% 0.21/0.44 % prop_preprocess_simplified: 2
% 0.21/0.44 % prop_fo_subsumed: 0
% 0.21/0.44 % prop_solver_time: 0.
% 0.21/0.44 % prop_fast_solver_time: 0.
% 0.21/0.44 % prop_unsat_core_time: 0.
% 0.21/0.44
% 0.21/0.44 % ------ QBF
% 0.21/0.44
% 0.21/0.44 % qbf_q_res: 0
% 0.21/0.44 % qbf_num_tautologies: 0
% 0.21/0.44 % qbf_prep_cycles: 0
% 0.21/0.44
% 0.21/0.44 % ------ BMC1
% 0.21/0.44
% 0.21/0.44 % bmc1_current_bound: -1
% 0.21/0.44 % bmc1_last_solved_bound: -1
% 0.21/0.44 % bmc1_unsat_core_size: -1
% 0.21/0.44 % bmc1_unsat_core_parents_size: -1
% 0.21/0.44 % bmc1_merge_next_fun: 0
% 0.21/0.44 % bmc1_unsat_core_clauses_time: 0.
% 0.21/0.44
% 0.21/0.44 % ------ Instantiation
% 0.21/0.44
% 0.21/0.44 % inst_num_of_clauses: undef
% 0.21/0.44 % inst_num_in_passive: undef
% 0.21/0.44 % inst_num_in_active: 0
% 0.21/0.44 % inst_num_in_unprocessed: 0
% 0.21/0.44 % inst_num_of_loops: 0
% 0.21/0.44 % inst_num_of_learning_restarts: 0
% 0.21/0.44 % inst_num_moves_active_passive: 0
% 0.21/0.44 % inst_lit_activity: 0
% 0.21/0.44 % inst_lit_activity_moves: 0
% 0.21/0.44 % inst_num_tautologies: 0
% 0.21/0.44 % inst_num_prop_implied: 0
% 0.21/0.44 % inst_num_existing_simplified: 0
% 0.21/0.44 % inst_num_eq_res_simplified: 0
% 0.21/0.44 % inst_num_child_elim: 0
% 0.21/0.44 % inst_num_of_dismatching_blockings: 0
% 0.21/0.44 % inst_num_of_non_proper_insts: 0
% 0.21/0.44 % inst_num_of_duplicates: 0
% 0.21/0.44 % inst_inst_num_from_inst_to_res: 0
% 0.21/0.44 % inst_dismatching_checking_time: 0.
% 0.21/0.44
% 0.21/0.44 % ------ Resolution
% 0.21/0.44
% 0.21/0.44 % res_num_of_clauses: undef
% 0.21/0.44 % res_num_in_passive: undef
% 0.21/0.44 % res_num_in_active: 0
% 0.21/0.44 % res_num_of_loops: 0
% 0.21/0.44 % res_forward_subset_subsumed: 0
% 0.21/0.44 % res_backward_subset_subsumed: 0
% 0.21/0.44 % res_forward_subsumed: 0
% 0.21/0.44 % res_backward_subsumed: 0
% 0.21/0.44 % res_forward_subsumption_resolution: 0
% 0.21/0.44 % res_backward_subsumption_resolution: 0
% 0.21/0.44 % res_clause_to_clause_subsumption: 0
% 0.21/0.44 % res_orphan_elimination: 0
% 0.21/0.44 % res_tautology_del: 0
% 0.21/0.44 % res_num_eq_res_simplified: 0
% 0.21/0.44 % res_num_sel_changes: 0
% 0.21/0.44 % res_moves_from_active_to_pass: 0
% 0.21/0.44
% 0.21/0.44 % Status Unsatisfiable
% 0.21/0.44 % SZS status Unsatisfiable
% 0.21/0.44 % SZS output start CNFRefutation
% See solution above
%------------------------------------------------------------------------------