TSTP Solution File: BOO004-4 by Moca---0.1

%------------------------------------------------------------------------------
% File     : Moca---0.1
% Problem  : BOO004-4 : TPTP v8.1.0. Released v1.1.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : moca.sh %s

% Computer : n018.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 : Thu Jul 14 23:46:14 EDT 2022

% Result   : Unsatisfiable 0.67s 0.83s
% Output   : Proof 0.67s
% Verified : 
% SZS Type : -

% Comments : 
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%----WARNING: Could not form TPTP format derivation
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%----ORIGINAL SYSTEM OUTPUT
% 0.03/0.12  % Problem  : BOO004-4 : TPTP v8.1.0. Released v1.1.0.
% 0.03/0.13  % Command  : moca.sh %s
% 0.12/0.34  % Computer : n018.cluster.edu
% 0.12/0.34  % Model    : x86_64 x86_64
% 0.12/0.34  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.12/0.34  % Memory   : 8042.1875MB
% 0.12/0.34  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.12/0.34  % CPULimit : 300
% 0.12/0.34  % WCLimit  : 600
% 0.12/0.34  % DateTime : Wed Jun  1 16:57:14 EDT 2022
% 0.12/0.34  % CPUTime  : 
% 0.67/0.83  % SZS status Unsatisfiable
% 0.67/0.83  % SZS output start Proof
% 0.67/0.83  The input problem is unsatisfiable because
% 0.67/0.83  
% 0.67/0.83  [1] the following set of Horn clauses is unsatisfiable:
% 0.67/0.83  
% 0.67/0.83  	add(X, Y) = add(Y, X)
% 0.67/0.83  	multiply(X, Y) = multiply(Y, X)
% 0.67/0.83  	add(X, multiply(Y, Z)) = multiply(add(X, Y), add(X, Z))
% 0.67/0.83  	multiply(X, add(Y, Z)) = add(multiply(X, Y), multiply(X, Z))
% 0.67/0.83  	add(X, additive_identity) = X
% 0.67/0.83  	multiply(X, multiplicative_identity) = X
% 0.67/0.83  	add(X, inverse(X)) = multiplicative_identity
% 0.67/0.83  	multiply(X, inverse(X)) = additive_identity
% 0.67/0.83  	add(a, a) = a ==> \bottom
% 0.67/0.83  
% 0.67/0.83  This holds because
% 0.67/0.83  
% 0.67/0.83  [2] the following E entails the following G (Claessen-Smallbone's transformation (2018)):
% 0.67/0.83  
% 0.67/0.83  E:
% 0.67/0.83  	add(X, Y) = add(Y, X)
% 0.67/0.83  	add(X, additive_identity) = X
% 0.67/0.83  	add(X, inverse(X)) = multiplicative_identity
% 0.67/0.83  	add(X, multiply(Y, Z)) = multiply(add(X, Y), add(X, Z))
% 0.67/0.83  	f1(a) = false__
% 0.67/0.83  	f1(add(a, a)) = true__
% 0.67/0.83  	multiply(X, Y) = multiply(Y, X)
% 0.67/0.83  	multiply(X, add(Y, Z)) = add(multiply(X, Y), multiply(X, Z))
% 0.67/0.83  	multiply(X, inverse(X)) = additive_identity
% 0.67/0.83  	multiply(X, multiplicative_identity) = X
% 0.67/0.83  G:
% 0.67/0.83  	true__ = false__
% 0.67/0.83  
% 0.67/0.83  This holds because
% 0.67/0.83  
% 0.67/0.83  [3] E entails the following ordered TRS and the lhs and rhs of G join by the TRS:
% 0.67/0.83  
% 0.67/0.83  	add(X, Y) = add(Y, X)
% 0.67/0.83  	multiply(X, Y) = multiply(Y, X)
% 0.67/0.83  	multiply(Y0, add(Y0, Y2)) = multiply(Y0, add(multiplicative_identity, Y2))
% 0.67/0.83  	multiply(add(Y0, Y0), add(Y0, Y1)) = multiply(Y0, add(Y1, multiplicative_identity))
% 0.67/0.83  	multiply(add(Y0, Y0), add(Y0, Y2)) = multiply(Y0, add(multiplicative_identity, Y2))
% 0.67/0.83  	add(X, additive_identity) -> X
% 0.67/0.83  	add(X, inverse(X)) -> multiplicative_identity
% 0.67/0.83  	add(X, multiply(Y, Z)) -> multiply(add(X, Y), add(X, Z))
% 0.67/0.83  	add(Y0, inverse(inverse(Y0))) -> Y0
% 0.67/0.83  	add(Y0, multiplicative_identity) -> multiplicative_identity
% 0.67/0.83  	add(Y1, Y1) -> Y1
% 0.67/0.83  	add(additive_identity, Y0) -> Y0
% 0.67/0.83  	add(multiplicative_identity, Y0) -> multiplicative_identity
% 0.67/0.83  	add(multiplicative_identity, multiplicative_identity) -> multiplicative_identity
% 0.67/0.83  	add(multiply(X, Y), multiply(X, Z)) -> multiply(X, add(Y, Z))
% 0.67/0.83  	f1(a) -> false__
% 0.67/0.83  	f1(add(a, a)) -> true__
% 0.67/0.83  	inverse(additive_identity) -> multiplicative_identity
% 0.67/0.83  	inverse(multiplicative_identity) -> additive_identity
% 0.67/0.83  	multiply(X, inverse(X)) -> additive_identity
% 0.67/0.83  	multiply(X, multiplicative_identity) -> X
% 0.67/0.83  	multiply(Y0, Y0) -> Y0
% 0.67/0.83  	multiply(Y0, add(Y0, Y0)) -> Y0
% 0.67/0.83  	multiply(Y0, add(Y0, Y1)) -> Y0
% 0.67/0.83  	multiply(Y0, add(Y0, inverse(additive_identity))) -> Y0
% 0.67/0.83  	multiply(Y0, add(Y0, multiplicative_identity)) -> Y0
% 0.67/0.83  	multiply(Y0, add(inverse(Y0), Y2)) -> multiply(add(additive_identity, Y0), add(additive_identity, Y2))
% 0.67/0.83  	multiply(Y0, add(multiplicative_identity, Y0)) -> Y0
% 0.67/0.83  	multiply(Y0, add(multiplicative_identity, inverse(Y0))) -> add(Y0, Y0)
% 0.67/0.83  	multiply(Y0, additive_identity) -> additive_identity
% 0.67/0.83  	multiply(add(Y0, Y1), add(Y0, inverse(Y1))) -> Y0
% 0.67/0.83  	multiply(add(Y0, Y1), add(Y0, multiplicative_identity)) -> add(Y0, Y1)
% 0.67/0.83  	multiply(additive_identity, Y0) -> additive_identity
% 0.67/0.83  	multiply(additive_identity, add(Y1, multiplicative_identity)) -> multiply(additive_identity, Y1)
% 0.67/0.83  	multiply(additive_identity, add(multiplicative_identity, Y1)) -> multiply(additive_identity, Y1)
% 0.67/0.83  	multiply(additive_identity, additive_identity) -> additive_identity
% 0.67/0.83  	multiply(multiplicative_identity, Y0) -> Y0
% 0.67/0.83  	true__ -> false__
% 0.67/0.83  with the LPO induced by
% 0.67/0.83  	a > f1 > inverse > additive_identity > add > multiply > multiplicative_identity > true__ > false__
% 0.67/0.83  
% 0.67/0.83  % SZS output end Proof
% 0.67/0.83  
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