TSTP Solution File: GRP615-1 by CSE_E---1.5
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%------------------------------------------------------------------------------
% File : CSE_E---1.5
% Problem : GRP615-1 : TPTP v8.1.2. Released v2.6.0.
% Transfm : none
% Format : tptp:raw
% Command : java -jar /export/starexec/sandbox/solver/bin/mcs_scs.jar %d %s
% Computer : n028.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 : Thu Aug 31 00:21:49 EDT 2023
% Result : Unsatisfiable 0.60s 0.68s
% Output : CNFRefutation 0.60s
% Verified :
% SZS Type : Refutation
% Derivation depth : 19
% Number of leaves : 9
% Syntax : Number of formulae : 40 ( 34 unt; 6 typ; 0 def)
% Number of atoms : 34 ( 33 equ)
% Maximal formula atoms : 1 ( 1 avg)
% Number of connectives : 5 ( 5 ~; 0 |; 0 &)
% ( 0 <=>; 0 =>; 0 <=; 0 <~>)
% Maximal formula depth : 2 ( 1 avg)
% Maximal term depth : 11 ( 2 avg)
% Number of types : 1 ( 0 usr)
% Number of type conns : 5 ( 3 >; 2 *; 0 +; 0 <<)
% Number of predicates : 2 ( 0 usr; 1 prp; 0-2 aty)
% Number of functors : 6 ( 6 usr; 3 con; 0-2 aty)
% Number of variables : 66 ( 0 sgn; 0 !; 0 ?; 0 :)
% Comments :
%------------------------------------------------------------------------------
tff(decl_22,type,
inverse: $i > $i ).
tff(decl_23,type,
double_divide: ( $i * $i ) > $i ).
tff(decl_24,type,
multiply: ( $i * $i ) > $i ).
tff(decl_25,type,
a3: $i ).
tff(decl_26,type,
b3: $i ).
tff(decl_27,type,
c3: $i ).
cnf(single_axiom,axiom,
double_divide(inverse(double_divide(inverse(double_divide(X1,inverse(X2))),X3)),double_divide(X1,X3)) = X2,
file('/export/starexec/sandbox/benchmark/theBenchmark.p',single_axiom) ).
cnf(prove_these_axioms_3,negated_conjecture,
multiply(multiply(a3,b3),c3) != multiply(a3,multiply(b3,c3)),
file('/export/starexec/sandbox/benchmark/theBenchmark.p',prove_these_axioms_3) ).
cnf(multiply,axiom,
multiply(X1,X2) = inverse(double_divide(X2,X1)),
file('/export/starexec/sandbox/benchmark/theBenchmark.p',multiply) ).
cnf(c_0_3,axiom,
double_divide(inverse(double_divide(inverse(double_divide(X1,inverse(X2))),X3)),double_divide(X1,X3)) = X2,
single_axiom ).
cnf(c_0_4,plain,
double_divide(inverse(double_divide(inverse(double_divide(inverse(double_divide(inverse(double_divide(X1,inverse(X2))),X3)),inverse(X4))),double_divide(X1,X3))),X2) = X4,
inference(spm,[status(thm)],[c_0_3,c_0_3]) ).
cnf(c_0_5,plain,
double_divide(inverse(double_divide(inverse(X1),inverse(X2))),X1) = X2,
inference(rw,[status(thm)],[inference(spm,[status(thm)],[c_0_4,c_0_4]),c_0_3]) ).
cnf(c_0_6,plain,
double_divide(inverse(X1),double_divide(inverse(X2),X2)) = X1,
inference(spm,[status(thm)],[c_0_3,c_0_5]) ).
cnf(c_0_7,plain,
double_divide(inverse(X1),double_divide(inverse(double_divide(X2,inverse(X1))),double_divide(X2,inverse(X3)))) = X3,
inference(spm,[status(thm)],[c_0_3,c_0_3]) ).
cnf(c_0_8,plain,
double_divide(inverse(double_divide(inverse(X1),X1)),inverse(X2)) = X2,
inference(spm,[status(thm)],[c_0_5,c_0_6]) ).
cnf(c_0_9,plain,
double_divide(inverse(X1),double_divide(inverse(X1),X2)) = X2,
inference(rw,[status(thm)],[inference(spm,[status(thm)],[c_0_7,c_0_8]),c_0_8]) ).
cnf(c_0_10,plain,
double_divide(inverse(double_divide(inverse(X1),X1)),X2) = inverse(X2),
inference(spm,[status(thm)],[c_0_9,c_0_8]) ).
cnf(c_0_11,plain,
inverse(inverse(X1)) = X1,
inference(rw,[status(thm)],[c_0_8,c_0_10]) ).
cnf(c_0_12,plain,
double_divide(X1,double_divide(inverse(X2),X2)) = inverse(X1),
inference(spm,[status(thm)],[c_0_6,c_0_11]) ).
cnf(c_0_13,plain,
double_divide(inverse(X1),double_divide(X2,inverse(X1))) = X2,
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(spm,[status(thm)],[c_0_7,c_0_12]),c_0_11]),c_0_11]) ).
cnf(c_0_14,plain,
inverse(double_divide(X1,inverse(X2))) = double_divide(inverse(X1),X2),
inference(rw,[status(thm)],[inference(spm,[status(thm)],[c_0_13,c_0_5]),c_0_11]) ).
cnf(c_0_15,plain,
double_divide(double_divide(X1,X2),X1) = X2,
inference(rw,[status(thm)],[inference(rw,[status(thm)],[c_0_5,c_0_14]),c_0_11]) ).
cnf(c_0_16,plain,
double_divide(X1,double_divide(X1,X2)) = X2,
inference(spm,[status(thm)],[c_0_9,c_0_11]) ).
cnf(c_0_17,plain,
double_divide(X1,X2) = double_divide(X2,X1),
inference(spm,[status(thm)],[c_0_15,c_0_16]) ).
cnf(c_0_18,plain,
double_divide(inverse(X1),X1) = double_divide(inverse(X2),X2),
inference(spm,[status(thm)],[c_0_9,c_0_6]) ).
cnf(c_0_19,plain,
double_divide(X1,inverse(double_divide(double_divide(X2,X3),double_divide(double_divide(double_divide(inverse(X2),X1),X3),X4)))) = X4,
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[c_0_4,c_0_17]),c_0_14]),c_0_14]),c_0_11]),c_0_17]) ).
cnf(c_0_20,plain,
double_divide(X1,inverse(X1)) = double_divide(X2,inverse(X2)),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[c_0_18,c_0_17]),c_0_17]) ).
cnf(c_0_21,plain,
double_divide(X1,double_divide(X2,inverse(X2))) = inverse(X1),
inference(spm,[status(thm)],[c_0_12,c_0_11]) ).
cnf(c_0_22,negated_conjecture,
multiply(multiply(a3,b3),c3) != multiply(a3,multiply(b3,c3)),
prove_these_axioms_3 ).
cnf(c_0_23,axiom,
multiply(X1,X2) = inverse(double_divide(X2,X1)),
multiply ).
cnf(c_0_24,plain,
inverse(double_divide(double_divide(inverse(X1),X2),X3)) = double_divide(X2,double_divide(X1,X3)),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(spm,[status(thm)],[c_0_19,c_0_20]),c_0_21]),c_0_11]) ).
cnf(c_0_25,negated_conjecture,
inverse(double_divide(c3,inverse(double_divide(b3,a3)))) != inverse(double_divide(inverse(double_divide(c3,b3)),a3)),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[c_0_22,c_0_23]),c_0_23]),c_0_23]),c_0_23]) ).
cnf(c_0_26,plain,
inverse(double_divide(double_divide(X1,X2),X3)) = double_divide(X2,double_divide(inverse(X1),X3)),
inference(spm,[status(thm)],[c_0_24,c_0_11]) ).
cnf(c_0_27,plain,
double_divide(inverse(X1),inverse(X2)) = inverse(double_divide(X1,X2)),
inference(spm,[status(thm)],[c_0_14,c_0_11]) ).
cnf(c_0_28,plain,
inverse(double_divide(inverse(X1),X2)) = double_divide(X1,inverse(X2)),
inference(spm,[status(thm)],[c_0_11,c_0_14]) ).
cnf(c_0_29,negated_conjecture,
inverse(double_divide(inverse(double_divide(c3,b3)),a3)) != double_divide(inverse(c3),double_divide(b3,a3)),
inference(rw,[status(thm)],[c_0_25,c_0_14]) ).
cnf(c_0_30,plain,
double_divide(double_divide(X1,X2),inverse(X3)) = double_divide(inverse(X2),double_divide(X1,X3)),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(spm,[status(thm)],[c_0_26,c_0_27]),c_0_28]),c_0_11]) ).
cnf(c_0_31,negated_conjecture,
double_divide(double_divide(b3,a3),inverse(c3)) != double_divide(double_divide(c3,b3),inverse(a3)),
inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[c_0_29,c_0_17]),c_0_14]),c_0_17]),c_0_17]) ).
cnf(c_0_32,plain,
double_divide(double_divide(X1,X2),inverse(X3)) = double_divide(double_divide(X1,X3),inverse(X2)),
inference(spm,[status(thm)],[c_0_17,c_0_30]) ).
cnf(c_0_33,negated_conjecture,
$false,
inference(cn,[status(thm)],[inference(rw,[status(thm)],[inference(rw,[status(thm)],[c_0_31,c_0_32]),c_0_17])]),
[proof] ).
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.12/0.12 % Problem : GRP615-1 : TPTP v8.1.2. Released v2.6.0.
% 0.12/0.12 % Command : java -jar /export/starexec/sandbox/solver/bin/mcs_scs.jar %d %s
% 0.12/0.33 % Computer : n028.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 : Mon Aug 28 21:30:25 EDT 2023
% 0.12/0.33 % CPUTime :
% 0.18/0.55 start to proof: theBenchmark
% 0.60/0.68 % Version : CSE_E---1.5
% 0.60/0.68 % Problem : theBenchmark.p
% 0.60/0.68 % Proof found
% 0.60/0.68 % SZS status Theorem for theBenchmark.p
% 0.60/0.68 % SZS output start Proof
% See solution above
% 0.60/0.68 % Total time : 0.123000 s
% 0.60/0.68 % SZS output end Proof
% 0.60/0.68 % Total time : 0.126000 s
%------------------------------------------------------------------------------