TSTP Solution File: GRP157-1 by Moca---0.1
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- Process Solution
%------------------------------------------------------------------------------
% File : Moca---0.1
% Problem : GRP157-1 : TPTP v8.1.0. Bugfixed v1.2.1.
% Transfm : none
% Format : tptp:raw
% Command : moca.sh %s
% Computer : n029.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 : Sat Jul 16 10:53:30 EDT 2022
% Result : Unsatisfiable 1.43s 1.57s
% Output : Proof 1.43s
% Verified :
% SZS Type : -
% Comments :
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%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.11/0.11 % Problem : GRP157-1 : TPTP v8.1.0. Bugfixed v1.2.1.
% 0.11/0.12 % Command : moca.sh %s
% 0.13/0.33 % Computer : n029.cluster.edu
% 0.13/0.33 % Model : x86_64 x86_64
% 0.13/0.33 % CPU : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.13/0.33 % Memory : 8042.1875MB
% 0.13/0.33 % OS : Linux 3.10.0-693.el7.x86_64
% 0.13/0.33 % CPULimit : 300
% 0.13/0.33 % WCLimit : 600
% 0.13/0.33 % DateTime : Mon Jun 13 21:03:10 EDT 2022
% 0.13/0.33 % CPUTime :
% 1.43/1.57 % SZS status Unsatisfiable
% 1.43/1.57 % SZS output start Proof
% 1.43/1.57 The input problem is unsatisfiable because
% 1.43/1.57
% 1.43/1.57 [1] the following set of Horn clauses is unsatisfiable:
% 1.43/1.57
% 1.43/1.57 multiply(identity, X) = X
% 1.43/1.57 multiply(inverse(X), X) = identity
% 1.43/1.57 multiply(multiply(X, Y), Z) = multiply(X, multiply(Y, Z))
% 1.43/1.57 greatest_lower_bound(X, Y) = greatest_lower_bound(Y, X)
% 1.43/1.57 least_upper_bound(X, Y) = least_upper_bound(Y, X)
% 1.43/1.57 greatest_lower_bound(X, greatest_lower_bound(Y, Z)) = greatest_lower_bound(greatest_lower_bound(X, Y), Z)
% 1.43/1.57 least_upper_bound(X, least_upper_bound(Y, Z)) = least_upper_bound(least_upper_bound(X, Y), Z)
% 1.43/1.57 least_upper_bound(X, X) = X
% 1.43/1.57 greatest_lower_bound(X, X) = X
% 1.43/1.57 least_upper_bound(X, greatest_lower_bound(X, Y)) = X
% 1.43/1.57 greatest_lower_bound(X, least_upper_bound(X, Y)) = X
% 1.43/1.57 multiply(X, least_upper_bound(Y, Z)) = least_upper_bound(multiply(X, Y), multiply(X, Z))
% 1.43/1.57 multiply(X, greatest_lower_bound(Y, Z)) = greatest_lower_bound(multiply(X, Y), multiply(X, Z))
% 1.43/1.57 multiply(least_upper_bound(Y, Z), X) = least_upper_bound(multiply(Y, X), multiply(Z, X))
% 1.43/1.57 multiply(greatest_lower_bound(Y, Z), X) = greatest_lower_bound(multiply(Y, X), multiply(Z, X))
% 1.43/1.57 least_upper_bound(a, b) = b
% 1.43/1.57 least_upper_bound(multiply(c, a), multiply(c, b)) = multiply(c, b) ==> \bottom
% 1.43/1.57
% 1.43/1.57 This holds because
% 1.43/1.57
% 1.43/1.57 [2] the following E entails the following G (Claessen-Smallbone's transformation (2018)):
% 1.43/1.57
% 1.43/1.57 E:
% 1.43/1.57 f1(least_upper_bound(multiply(c, a), multiply(c, b))) = true__
% 1.43/1.57 f1(multiply(c, b)) = false__
% 1.43/1.57 greatest_lower_bound(X, X) = X
% 1.43/1.57 greatest_lower_bound(X, Y) = greatest_lower_bound(Y, X)
% 1.43/1.57 greatest_lower_bound(X, greatest_lower_bound(Y, Z)) = greatest_lower_bound(greatest_lower_bound(X, Y), Z)
% 1.43/1.57 greatest_lower_bound(X, least_upper_bound(X, Y)) = X
% 1.43/1.57 least_upper_bound(X, X) = X
% 1.43/1.57 least_upper_bound(X, Y) = least_upper_bound(Y, X)
% 1.43/1.57 least_upper_bound(X, greatest_lower_bound(X, Y)) = X
% 1.43/1.57 least_upper_bound(X, least_upper_bound(Y, Z)) = least_upper_bound(least_upper_bound(X, Y), Z)
% 1.43/1.57 least_upper_bound(a, b) = b
% 1.43/1.57 multiply(X, greatest_lower_bound(Y, Z)) = greatest_lower_bound(multiply(X, Y), multiply(X, Z))
% 1.43/1.57 multiply(X, least_upper_bound(Y, Z)) = least_upper_bound(multiply(X, Y), multiply(X, Z))
% 1.43/1.57 multiply(greatest_lower_bound(Y, Z), X) = greatest_lower_bound(multiply(Y, X), multiply(Z, X))
% 1.43/1.57 multiply(identity, X) = X
% 1.43/1.57 multiply(inverse(X), X) = identity
% 1.43/1.57 multiply(least_upper_bound(Y, Z), X) = least_upper_bound(multiply(Y, X), multiply(Z, X))
% 1.43/1.57 multiply(multiply(X, Y), Z) = multiply(X, multiply(Y, Z))
% 1.43/1.57 G:
% 1.43/1.57 true__ = false__
% 1.43/1.57
% 1.43/1.57 This holds because
% 1.43/1.57
% 1.43/1.57 [3] E entails the following ordered TRS and the lhs and rhs of G join by the TRS:
% 1.43/1.57
% 1.43/1.57 greatest_lower_bound(X, Y) = greatest_lower_bound(Y, X)
% 1.43/1.57 greatest_lower_bound(Y1, greatest_lower_bound(Y0, Y2)) = greatest_lower_bound(Y0, greatest_lower_bound(Y1, Y2))
% 1.43/1.57 greatest_lower_bound(Y1, multiply(Y0, Y1)) = multiply(greatest_lower_bound(Y0, identity), Y1)
% 1.43/1.57 greatest_lower_bound(Y1, multiply(Y2, Y1)) = multiply(greatest_lower_bound(identity, Y2), Y1)
% 1.43/1.57 greatest_lower_bound(Y2, greatest_lower_bound(Y0, Y1)) = greatest_lower_bound(Y0, greatest_lower_bound(Y1, Y2))
% 1.43/1.57 greatest_lower_bound(identity, multiply(inverse(Y1), Y2)) = multiply(inverse(Y1), greatest_lower_bound(Y1, Y2))
% 1.43/1.57 greatest_lower_bound(identity, multiply(inverse(Y2), Y1)) = multiply(inverse(Y2), greatest_lower_bound(Y1, Y2))
% 1.43/1.57 greatest_lower_bound(multiply(Y0, Y1), identity) = multiply(greatest_lower_bound(Y0, inverse(Y1)), Y1)
% 1.43/1.57 least_upper_bound(X, Y) = least_upper_bound(Y, X)
% 1.43/1.57 least_upper_bound(Y1, least_upper_bound(Y0, Y2)) = least_upper_bound(Y0, least_upper_bound(Y1, Y2))
% 1.43/1.57 least_upper_bound(Y1, multiply(Y0, Y1)) = multiply(least_upper_bound(Y0, identity), Y1)
% 1.43/1.57 least_upper_bound(Y1, multiply(Y2, Y1)) = multiply(least_upper_bound(identity, Y2), Y1)
% 1.43/1.57 least_upper_bound(Y2, least_upper_bound(Y0, Y1)) = least_upper_bound(Y0, least_upper_bound(Y1, Y2))
% 1.43/1.57 least_upper_bound(identity, multiply(inverse(Y1), Y2)) = multiply(inverse(Y1), least_upper_bound(Y1, Y2))
% 1.43/1.57 least_upper_bound(identity, multiply(inverse(Y2), Y1)) = multiply(inverse(Y2), least_upper_bound(Y1, Y2))
% 1.43/1.57 least_upper_bound(multiply(Y0, Y1), identity) = multiply(least_upper_bound(Y0, inverse(Y1)), Y1)
% 1.43/1.57 f1(least_upper_bound(multiply(c, a), multiply(c, b))) -> true__
% 1.43/1.57 f1(multiply(c, b)) -> false__
% 1.43/1.57 greatest_lower_bound(X, X) -> X
% 1.43/1.57 greatest_lower_bound(X, least_upper_bound(X, Y)) -> X
% 1.43/1.57 greatest_lower_bound(Y0, greatest_lower_bound(Y1, greatest_lower_bound(Y0, Y1))) -> greatest_lower_bound(Y0, Y1)
% 1.43/1.57 greatest_lower_bound(Y0, greatest_lower_bound(Y1, least_upper_bound(greatest_lower_bound(Y0, Y1), X1))) -> greatest_lower_bound(Y0, Y1)
% 1.43/1.57 greatest_lower_bound(Y0, greatest_lower_bound(least_upper_bound(Y0, X1), Y2)) -> greatest_lower_bound(Y0, Y2)
% 1.43/1.57 greatest_lower_bound(Y0, least_upper_bound(Y1, Y0)) -> Y0
% 1.43/1.57 greatest_lower_bound(Y1, greatest_lower_bound(Y1, Y2)) -> greatest_lower_bound(Y1, Y2)
% 1.43/1.57 greatest_lower_bound(a, b) -> a
% 1.43/1.57 greatest_lower_bound(greatest_lower_bound(X, Y), Z) -> greatest_lower_bound(X, greatest_lower_bound(Y, Z))
% 1.43/1.57 greatest_lower_bound(least_upper_bound(X0, X1), least_upper_bound(X0, least_upper_bound(X1, Y1))) -> least_upper_bound(X0, X1)
% 1.43/1.57 greatest_lower_bound(multiply(X, Y), multiply(X, Z)) -> multiply(X, greatest_lower_bound(Y, Z))
% 1.43/1.57 greatest_lower_bound(multiply(X0, greatest_lower_bound(X1, X2)), Y2) -> greatest_lower_bound(multiply(X0, X1), greatest_lower_bound(multiply(X0, X2), Y2))
% 1.43/1.57 greatest_lower_bound(multiply(X0, multiply(X1, Y1)), multiply(Y2, Y1)) -> multiply(greatest_lower_bound(multiply(X0, X1), Y2), Y1)
% 1.43/1.57 greatest_lower_bound(multiply(Y, X), multiply(Z, X)) -> multiply(greatest_lower_bound(Y, Z), X)
% 1.43/1.57 greatest_lower_bound(multiply(Y0, Y1), multiply(X0, multiply(X1, Y1))) -> multiply(greatest_lower_bound(Y0, multiply(X0, X1)), Y1)
% 1.43/1.57 greatest_lower_bound(multiply(greatest_lower_bound(X0, X2), X1), Y2) -> greatest_lower_bound(multiply(X0, X1), greatest_lower_bound(multiply(X2, X1), Y2))
% 1.43/1.57 least_upper_bound(X, X) -> X
% 1.43/1.57 least_upper_bound(X, greatest_lower_bound(X, Y)) -> X
% 1.43/1.57 least_upper_bound(Y0, greatest_lower_bound(Y1, Y0)) -> Y0
% 1.43/1.57 least_upper_bound(Y0, least_upper_bound(Y1, greatest_lower_bound(least_upper_bound(Y0, Y1), X1))) -> least_upper_bound(Y0, Y1)
% 1.43/1.57 least_upper_bound(Y0, least_upper_bound(Y1, least_upper_bound(Y0, Y1))) -> least_upper_bound(Y0, Y1)
% 1.43/1.57 least_upper_bound(Y0, least_upper_bound(greatest_lower_bound(Y0, X1), Y2)) -> least_upper_bound(Y0, Y2)
% 1.43/1.57 least_upper_bound(Y1, least_upper_bound(Y1, Y2)) -> least_upper_bound(Y1, Y2)
% 1.43/1.57 least_upper_bound(a, b) -> b
% 1.43/1.57 least_upper_bound(a, least_upper_bound(b, Y2)) -> least_upper_bound(b, Y2)
% 1.43/1.57 least_upper_bound(greatest_lower_bound(X0, X1), greatest_lower_bound(X0, greatest_lower_bound(X1, Y1))) -> greatest_lower_bound(X0, X1)
% 1.43/1.57 least_upper_bound(least_upper_bound(X, Y), Z) -> least_upper_bound(X, least_upper_bound(Y, Z))
% 1.43/1.57 least_upper_bound(multiply(X, Y), multiply(X, Z)) -> multiply(X, least_upper_bound(Y, Z))
% 1.43/1.57 least_upper_bound(multiply(X0, least_upper_bound(X1, X2)), Y2) -> least_upper_bound(multiply(X0, X1), least_upper_bound(multiply(X0, X2), Y2))
% 1.43/1.57 least_upper_bound(multiply(X0, multiply(X1, Y1)), multiply(Y2, Y1)) -> multiply(least_upper_bound(multiply(X0, X1), Y2), Y1)
% 1.43/1.57 least_upper_bound(multiply(Y, X), multiply(Z, X)) -> multiply(least_upper_bound(Y, Z), X)
% 1.43/1.57 least_upper_bound(multiply(Y0, Y1), multiply(X0, multiply(X1, Y1))) -> multiply(least_upper_bound(Y0, multiply(X0, X1)), Y1)
% 1.43/1.57 least_upper_bound(multiply(least_upper_bound(X0, X2), X1), Y2) -> least_upper_bound(multiply(X0, X1), least_upper_bound(multiply(X2, X1), Y2))
% 1.43/1.57 multiply(greatest_lower_bound(inverse(Y1), Y2), Y1) -> greatest_lower_bound(identity, multiply(Y2, Y1))
% 1.43/1.57 multiply(identity, X) -> X
% 1.43/1.57 multiply(inverse(X), X) -> identity
% 1.43/1.57 multiply(inverse(Y1), multiply(Y1, Y2)) -> Y2
% 1.43/1.57 multiply(least_upper_bound(inverse(Y1), Y2), Y1) -> least_upper_bound(identity, multiply(Y2, Y1))
% 1.43/1.57 multiply(multiply(X, Y), Z) -> multiply(X, multiply(Y, Z))
% 1.43/1.57 true__ -> false__
% 1.43/1.57 with the LPO induced by
% 1.43/1.57 c > f1 > b > a > inverse > identity > greatest_lower_bound > least_upper_bound > multiply > true__ > false__
% 1.43/1.57
% 1.43/1.57 % SZS output end Proof
% 1.43/1.57
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