TSTP Solution File: CSR130^2 by cvc5---1.0.5
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- Process Solution
%------------------------------------------------------------------------------
% File : cvc5---1.0.5
% Problem : CSR130^2 : TPTP v8.1.2. Released v4.1.0.
% Transfm : none
% Format : tptp
% Command : do_cvc5 %s %d
% Computer : n017.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 : Wed Aug 30 21:07:08 EDT 2023
% Result : Theorem 0.20s 0.59s
% Output : Proof 0.20s
% Verified :
% SZS Type : -
% Comments :
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.07/0.13 % Problem : CSR130^2 : TPTP v8.1.2. Released v4.1.0.
% 0.07/0.14 % Command : do_cvc5 %s %d
% 0.14/0.36 % Computer : n017.cluster.edu
% 0.14/0.36 % Model : x86_64 x86_64
% 0.14/0.36 % CPU : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.14/0.36 % Memory : 8042.1875MB
% 0.14/0.36 % OS : Linux 3.10.0-693.el7.x86_64
% 0.14/0.36 % CPULimit : 300
% 0.14/0.36 % WCLimit : 300
% 0.14/0.36 % DateTime : Mon Aug 28 07:12:42 EDT 2023
% 0.14/0.36 % CPUTime :
% 0.20/0.50 %----Proving TH0
% 0.20/0.50 %------------------------------------------------------------------------------
% 0.20/0.50 % File : CSR130^2 : TPTP v8.1.2. Released v4.1.0.
% 0.20/0.50 % Domain : Commonsense Reasoning
% 0.20/0.50 % Problem : In 2009, what's the common feeling between Sue and Mary, and Bill?
% 0.20/0.50 % Version : Especial > Augmented > Especial.
% 0.20/0.50 % English : In the context of year 2009: Does there exists a relation ?R that
% 0.20/0.50 % holds between Sue and Bill as well as between Mary and Bill?
% 0.20/0.50
% 0.20/0.50 % Refs : [Ben10] Benzmueller (2010), Email to Geoff Sutcliffe
% 0.20/0.50 % Source : [Ben10]
% 0.20/0.50 % Names : ef_rv_2.tq_SUMO_sine [Ben10]
% 0.20/0.50
% 0.20/0.50 % Status : Theorem
% 0.20/0.50 % Rating : 0.31 v8.1.0, 0.27 v7.5.0, 0.29 v7.4.0, 0.22 v7.2.0, 0.12 v7.1.0, 0.25 v7.0.0, 0.43 v6.4.0, 0.50 v6.3.0, 0.40 v6.2.0, 0.43 v6.1.0, 1.00 v6.0.0, 0.57 v5.5.0, 0.50 v5.4.0, 0.80 v5.1.0, 1.00 v5.0.0, 0.80 v4.1.0
% 0.20/0.50 % Syntax : Number of formulae : 112 ( 21 unt; 47 typ; 0 def)
% 0.20/0.50 % Number of atoms : 127 ( 6 equ; 5 cnn)
% 0.20/0.50 % Maximal formula atoms : 4 ( 1 avg)
% 0.20/0.50 % Number of connectives : 282 ( 5 ~; 2 |; 10 &; 244 @)
% 0.20/0.50 % ( 3 <=>; 18 =>; 0 <=; 0 <~>)
% 0.20/0.50 % Maximal formula depth : 10 ( 5 avg)
% 0.20/0.50 % Number of types : 3 ( 1 usr)
% 0.20/0.50 % Number of type conns : 59 ( 59 >; 0 *; 0 +; 0 <<)
% 0.20/0.50 % Number of symbols : 48 ( 46 usr; 24 con; 0-3 aty)
% 0.20/0.50 % Number of variables : 49 ( 0 ^; 48 !; 1 ?; 49 :)
% 0.20/0.50 % SPC : TH0_THM_EQU_NAR
% 0.20/0.50
% 0.20/0.50 % Comments : This is a simple test problem for reasoning in/about SUMO.
% 0.20/0.50 % Initally the problem has been hand generated in KIF syntax in
% 0.20/0.50 % SigmaKEE and then automatically translated by Benzmueller's
% 0.20/0.50 % KIF2TH0 translator into THF syntax.
% 0.20/0.50 % : The translation has been applied in two modes: local and SInE.
% 0.20/0.50 % The local mode only translates the local assumptions and the
% 0.20/0.50 % query. The SInE mode additionally translates the SInE-extract
% 0.20/0.50 % of the loaded knowledge base (usually SUMO).
% 0.20/0.50 % : The examples are selected to illustrate the benefits of
% 0.20/0.50 % higher-order reasoning in ontology reasoning.
% 0.20/0.50 % : Note that the universal predicate is excluded for ?R with the
% 0.20/0.50 % second conjunct in the query.
% 0.20/0.50 %------------------------------------------------------------------------------
% 0.20/0.50 %----The extracted signature
% 0.20/0.50 thf(numbers,type,
% 0.20/0.50 num: $tType ).
% 0.20/0.50
% 0.20/0.50 thf(agent_THFTYPE_i,type,
% 0.20/0.50 agent_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(attribute_THFTYPE_i,type,
% 0.20/0.50 attribute_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(domain_THFTYPE_IIiiIiioI,type,
% 0.20/0.50 domain_THFTYPE_IIiiIiioI: ( $i > $i ) > $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(domain_THFTYPE_IIiioIiioI,type,
% 0.20/0.50 domain_THFTYPE_IIiioIiioI: ( $i > $i > $o ) > $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(domain_THFTYPE_IiiioI,type,
% 0.20/0.50 domain_THFTYPE_IiiioI: $i > $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(equal_THFTYPE_i,type,
% 0.20/0.50 equal_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(holdsDuring_THFTYPE_IiooI,type,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI: $i > $o > $o ).
% 0.20/0.50
% 0.20/0.50 thf(instance_THFTYPE_IIiiIioI,type,
% 0.20/0.50 instance_THFTYPE_IIiiIioI: ( $i > $i ) > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(instance_THFTYPE_IIiioIioI,type,
% 0.20/0.50 instance_THFTYPE_IIiioIioI: ( $i > $i > $o ) > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(instance_THFTYPE_IIiooIioI,type,
% 0.20/0.50 instance_THFTYPE_IIiooIioI: ( $i > $o > $o ) > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(instance_THFTYPE_IiioI,type,
% 0.20/0.50 instance_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(lAnna_THFTYPE_i,type,
% 0.20/0.50 lAnna_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lAsymmetricRelation_THFTYPE_i,type,
% 0.20/0.50 lAsymmetricRelation_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lBeginFn_THFTYPE_IiiI,type,
% 0.20/0.50 lBeginFn_THFTYPE_IiiI: $i > $i ).
% 0.20/0.50
% 0.20/0.50 thf(lBen_THFTYPE_i,type,
% 0.20/0.50 lBen_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lBill_THFTYPE_i,type,
% 0.20/0.50 lBill_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lBinaryPredicate_THFTYPE_i,type,
% 0.20/0.50 lBinaryPredicate_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lBob_THFTYPE_i,type,
% 0.20/0.50 lBob_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lEndFn_THFTYPE_IiiI,type,
% 0.20/0.50 lEndFn_THFTYPE_IiiI: $i > $i ).
% 0.20/0.50
% 0.20/0.50 thf(lInteger_THFTYPE_i,type,
% 0.20/0.50 lInteger_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lMary_THFTYPE_i,type,
% 0.20/0.50 lMary_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lMeasureFn_THFTYPE_i,type,
% 0.20/0.50 lMeasureFn_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lProcess_THFTYPE_i,type,
% 0.20/0.50 lProcess_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lSue_THFTYPE_i,type,
% 0.20/0.50 lSue_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lTemporalRelation_THFTYPE_i,type,
% 0.20/0.50 lTemporalRelation_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lTimeInterval_THFTYPE_i,type,
% 0.20/0.50 lTimeInterval_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lTotalValuedRelation_THFTYPE_i,type,
% 0.20/0.50 lTotalValuedRelation_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lUnaryFunction_THFTYPE_i,type,
% 0.20/0.50 lUnaryFunction_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lWhenFn_THFTYPE_IiiI,type,
% 0.20/0.50 lWhenFn_THFTYPE_IiiI: $i > $i ).
% 0.20/0.50
% 0.20/0.50 thf(lWhenFn_THFTYPE_i,type,
% 0.20/0.50 lWhenFn_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(lYearFn_THFTYPE_IiiI,type,
% 0.20/0.50 lYearFn_THFTYPE_IiiI: $i > $i ).
% 0.20/0.50
% 0.20/0.50 thf(likes_THFTYPE_IiioI,type,
% 0.20/0.50 likes_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(located_THFTYPE_IiioI,type,
% 0.20/0.50 located_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(meetsTemporally_THFTYPE_IiioI,type,
% 0.20/0.50 meetsTemporally_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(n1_THFTYPE_i,type,
% 0.20/0.50 n1_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(n2009_THFTYPE_i,type,
% 0.20/0.50 n2009_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(n2_THFTYPE_i,type,
% 0.20/0.50 n2_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(parent_THFTYPE_IiioI,type,
% 0.20/0.50 parent_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(part_THFTYPE_IiioI,type,
% 0.20/0.50 part_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(patient_THFTYPE_i,type,
% 0.20/0.50 patient_THFTYPE_i: $i ).
% 0.20/0.50
% 0.20/0.50 thf(range_THFTYPE_IiioI,type,
% 0.20/0.50 range_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(subProcess_THFTYPE_IiioI,type,
% 0.20/0.50 subProcess_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(subclass_THFTYPE_IiioI,type,
% 0.20/0.50 subclass_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(subrelation_THFTYPE_IIioIIioIoI,type,
% 0.20/0.50 subrelation_THFTYPE_IIioIIioIoI: ( $i > $o ) > ( $i > $o ) > $o ).
% 0.20/0.50
% 0.20/0.50 thf(subrelation_THFTYPE_IiioI,type,
% 0.20/0.50 subrelation_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 thf(temporalPart_THFTYPE_IiioI,type,
% 0.20/0.50 temporalPart_THFTYPE_IiioI: $i > $i > $o ).
% 0.20/0.50
% 0.20/0.50 %----The translated axioms
% 0.20/0.50 thf(ax,axiom,
% 0.20/0.50 ! [SUBPROC: $i,PROC: $i] :
% 0.20/0.50 ( ( subProcess_THFTYPE_IiioI @ SUBPROC @ PROC )
% 0.20/0.50 => ! [REGION: $i] :
% 0.20/0.50 ( ( located_THFTYPE_IiioI @ PROC @ REGION )
% 0.20/0.50 => ( located_THFTYPE_IiioI @ SUBPROC @ REGION ) ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation instance EnglishLanguage "An object is an &%instance of a &%SetOrClass if it is included in that &%SetOrClass. An individual may be an instance of many classes, some of which may be subclasses of others. Thus, there is no assumption in the meaning of &%instance about specificity or uniqueness.")
% 0.20/0.50 %KIF documentation:(documentation BeginFn EnglishLanguage "A &%UnaryFunction that maps a &%TimeInterval to the &%TimePoint at which the interval begins.")
% 0.20/0.50 %KIF documentation:(documentation EnglishLanguage EnglishLanguage "A Germanic language that incorporates many roots from the Romance languages. It is the official language of the &%UnitedStates, the &%UnitedKingdom, and many other countries.")
% 0.20/0.50 %KIF documentation:(documentation range EnglishLanguage "Gives the range of a function. In other words, (&%range ?FUNCTION ?CLASS) means that all of the values assigned by ?FUNCTION are &%instances of ?CLASS.")
% 0.20/0.50 %KIF documentation:(documentation patient EnglishLanguage "(&%patient ?PROCESS ?ENTITY) means that ?ENTITY is a participant in ?PROCESS that may be moved, said, experienced, etc. For example, the direct objects in the sentences 'The cat swallowed the canary' and 'Billy likes the beer' would be examples of &%patients. Note that the &%patient of a &%Process may or may not undergo structural change as a result of the &%Process. The &%CaseRole of &%patient is used when one wants to specify as broadly as possible the object of a &%Process.")
% 0.20/0.50 thf(ax_001,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( parent_THFTYPE_IiioI @ lMary_THFTYPE_i @ lBen_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation Process EnglishLanguage "The class of things that happen and have temporal parts or stages. Examples include extended events like a football match or a race, actions like &%Pursuing and &%Reading, and biological processes. The formal definition is: anything that occurs in time but is not an &%Object. Note that a &%Process may have participants 'inside' it which are &%Objects, such as the players in a football match. In a 4D ontology, a &%Process is something whose spatiotemporal extent is thought of as dividing into temporal stages roughly perpendicular to the time-axis.")
% 0.20/0.50 thf(ax_002,axiom,
% 0.20/0.50 ! [X: $i,Y: $i,Z: $i] :
% 0.20/0.50 ( ( ( subclass_THFTYPE_IiioI @ X @ Y )
% 0.20/0.50 & ( instance_THFTYPE_IiioI @ Z @ X ) )
% 0.20/0.50 => ( instance_THFTYPE_IiioI @ Z @ Y ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation TemporalRelation EnglishLanguage "The &%Class of temporal &%Relations. This &%Class includes notions of (temporal) topology of intervals, (temporal) schemata, and (temporal) extension.")
% 0.20/0.50 thf(ax_003,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( likes_THFTYPE_IiioI @ lSue_THFTYPE_i @ lBill_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_004,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( likes_THFTYPE_IiioI @ lSue_THFTYPE_i @ lBill_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_005,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( likes_THFTYPE_IiioI @ lMary_THFTYPE_i @ lBill_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_006,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( likes_THFTYPE_IiioI @ lMary_THFTYPE_i @ lBill_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_007,axiom,
% 0.20/0.50 ! [CLASS1: $i,CLASS2: $i] :
% 0.20/0.50 ( ( CLASS1 = CLASS2 )
% 0.20/0.50 => ! [THING: $i] :
% 0.20/0.50 ( ( instance_THFTYPE_IiioI @ THING @ CLASS1 )
% 0.20/0.50 <=> ( instance_THFTYPE_IiioI @ THING @ CLASS2 ) ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation TotalValuedRelation EnglishLanguage "A &%Relation is a &%TotalValuedRelation just in case there exists an assignment for the last argument position of the &%Relation given any assignment of values to every argument position except the last one. Note that declaring a &%Relation to be both a &%TotalValuedRelation and a &%SingleValuedRelation means that it is a total function.")
% 0.20/0.50 %KIF documentation:(documentation equal EnglishLanguage "(equal ?ENTITY1 ?ENTITY2) is true just in case ?ENTITY1 is identical with ?ENTITY2.")
% 0.20/0.50 %KIF documentation:(documentation AsymmetricRelation EnglishLanguage "A &%BinaryRelation is asymmetric if and only if it is both an &%AntisymmetricRelation and an &%IrreflexiveRelation.")
% 0.20/0.50 thf(ax_008,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( (~) @ ( likes_THFTYPE_IiioI @ lSue_THFTYPE_i @ lMary_THFTYPE_i ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_009,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( (~) @ ( likes_THFTYPE_IiioI @ lSue_THFTYPE_i @ lMary_THFTYPE_i ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation temporalPart EnglishLanguage "The temporal analogue of the spatial &%part predicate. (&%temporalPart ?POS1 ?POS2) means that &%TimePosition ?POS1 is part of &%TimePosition ?POS2. Note that since &%temporalPart is a &%ReflexiveRelation every &%TimePostion is a &%temporalPart of itself.")
% 0.20/0.50 thf(ax_010,axiom,
% 0.20/0.50 ! [REL2: $i > $o,ROW: $i,REL1: $i > $o] :
% 0.20/0.50 ( ( ( subrelation_THFTYPE_IIioIIioIoI @ REL1 @ REL2 )
% 0.20/0.50 & ( REL1 @ ROW ) )
% 0.20/0.50 => ( REL2 @ ROW ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation subrelation EnglishLanguage "(&%subrelation ?REL1 ?REL2) means that every tuple of ?REL1 is also a tuple of ?REL2. In other words, if the &%Relation ?REL1 holds for some arguments arg_1, arg_2, ... arg_n, then the &%Relation ?REL2 holds for the same arguments. A consequence of this is that a &%Relation and its subrelations must have the same &%valence.")
% 0.20/0.50 thf(ax_011,axiom,
% 0.20/0.50 ! [TIME: $i,SITUATION: $o] :
% 0.20/0.50 ( ( holdsDuring_THFTYPE_IiooI @ TIME @ ( (~) @ SITUATION ) )
% 0.20/0.50 => ( (~) @ ( holdsDuring_THFTYPE_IiooI @ TIME @ SITUATION ) ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_012,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( parent_THFTYPE_IiioI @ lSue_THFTYPE_i @ lAnna_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_013,axiom,
% 0.20/0.50 ! [OBJ1: $i,OBJ2: $i] :
% 0.20/0.50 ( ( located_THFTYPE_IiioI @ OBJ1 @ OBJ2 )
% 0.20/0.50 => ! [SUB: $i] :
% 0.20/0.50 ( ( part_THFTYPE_IiioI @ SUB @ OBJ1 )
% 0.20/0.50 => ( located_THFTYPE_IiioI @ SUB @ OBJ2 ) ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation YearFn EnglishLanguage "A &%UnaryFunction that maps a number to the corresponding calendar &%Year. For example, (&%YearFn 1912) returns the &%Class containing just one instance, the year of 1912. As might be expected, positive integers return years in the Common Era, while negative integers return years in B.C.E. Note that this function returns a &%Class as a value. The reason for this is that the related functions, viz. &%MonthFn, &%DayFn, &%HourFn, &%MinuteFn, and &%SecondFn, are used to generate both specific &%TimeIntervals and recurrent intervals, and the only way to do this is to make the domains and ranges of these functions classes rather than individuals.")
% 0.20/0.50 %KIF documentation:(documentation holdsDuring EnglishLanguage "(&%holdsDuring ?TIME ?FORMULA) means that the proposition denoted by ?FORMULA is true in the time frame ?TIME. Note that this implies that ?FORMULA is true at every &%TimePoint which is a &%temporalPart of ?TIME.")
% 0.20/0.50 %KIF documentation:(documentation subProcess EnglishLanguage "(&%subProcess ?SUBPROC ?PROC) means that ?SUBPROC is a subprocess of ?PROC. A subprocess is here understood as a temporally distinguished part (proper or not) of a &%Process.")
% 0.20/0.50 %KIF documentation:(documentation EndFn EnglishLanguage "A &%UnaryFunction that maps a &%TimeInterval to the &%TimePoint at which the interval ends.")
% 0.20/0.50 %KIF documentation:(documentation meetsTemporally EnglishLanguage "(&%meetsTemporally ?INTERVAL1 ?INTERVAL2) means that the terminal point of the &%TimeInterval ?INTERVAL1 is the initial point of the &%TimeInterval ?INTERVAL2.")
% 0.20/0.50 %KIF documentation:(documentation Integer EnglishLanguage "A negative or nonnegative whole number.")
% 0.20/0.50 thf(ax_014,axiom,
% 0.20/0.50 ! [THING2: $i,THING1: $i] :
% 0.20/0.50 ( ( THING1 = THING2 )
% 0.20/0.50 => ! [CLASS: $i] :
% 0.20/0.50 ( ( instance_THFTYPE_IiioI @ THING1 @ CLASS )
% 0.20/0.50 <=> ( instance_THFTYPE_IiioI @ THING2 @ CLASS ) ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_015,axiom,
% 0.20/0.50 ! [CLASS1: $i,REL: $i,CLASS2: $i] :
% 0.20/0.50 ( ( ( range_THFTYPE_IiioI @ REL @ CLASS1 )
% 0.20/0.50 & ( range_THFTYPE_IiioI @ REL @ CLASS2 ) )
% 0.20/0.50 => ( ( subclass_THFTYPE_IiioI @ CLASS1 @ CLASS2 )
% 0.20/0.50 | ( subclass_THFTYPE_IiioI @ CLASS2 @ CLASS1 ) ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation domain EnglishLanguage "Provides a computationally and heuristically convenient mechanism for declaring the argument types of a given relation. The formula (&%domain ?REL ?INT ?CLASS) means that the ?INT'th element of each tuple in the relation ?REL must be an instance of ?CLASS. Specifying argument types is very helpful in maintaining ontologies. Representation systems can use these specifications to classify terms and check integrity constraints. If the restriction on the argument type of a &%Relation is not captured by a &%SetOrClass already defined in the ontology, one can specify a &%SetOrClass compositionally with the functions &%UnionFn, &%IntersectionFn, etc.")
% 0.20/0.50 thf(ax_016,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( likes_THFTYPE_IiioI @ lBob_THFTYPE_i @ lBill_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation UnaryFunction EnglishLanguage "The &%Class of &%Functions that require a single argument.")
% 0.20/0.50 %KIF documentation:(documentation attribute EnglishLanguage "(&%attribute ?OBJECT ?PROPERTY) means that ?PROPERTY is a &%Attribute of ?OBJECT. For example, (&%attribute &%MyLittleRedWagon &%Red).")
% 0.20/0.50 thf(ax_017,axiom,
% 0.20/0.50 range_THFTYPE_IiioI @ lWhenFn_THFTYPE_i @ lTimeInterval_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_018,axiom,
% 0.20/0.50 ! [SUBPROC: $i,PROC: $i] :
% 0.20/0.50 ( ( subProcess_THFTYPE_IiioI @ SUBPROC @ PROC )
% 0.20/0.50 => ( temporalPart_THFTYPE_IiioI @ ( lWhenFn_THFTYPE_IiiI @ SUBPROC ) @ ( lWhenFn_THFTYPE_IiiI @ PROC ) ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_019,axiom,
% 0.20/0.50 ! [OBJ: $i,PROCESS: $i] :
% 0.20/0.50 ( ( located_THFTYPE_IiioI @ PROCESS @ OBJ )
% 0.20/0.50 => ! [SUB: $i] :
% 0.20/0.50 ( ( subProcess_THFTYPE_IiioI @ SUB @ PROCESS )
% 0.20/0.50 => ( located_THFTYPE_IiioI @ SUB @ OBJ ) ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_020,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( parent_THFTYPE_IiioI @ lSue_THFTYPE_i @ lBen_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_021,axiom,
% 0.20/0.50 ! [INTERVAL1: $i,INTERVAL2: $i] :
% 0.20/0.50 ( ( meetsTemporally_THFTYPE_IiioI @ INTERVAL1 @ INTERVAL2 )
% 0.20/0.50 <=> ( ( lEndFn_THFTYPE_IiiI @ INTERVAL1 )
% 0.20/0.50 = ( lBeginFn_THFTYPE_IiiI @ INTERVAL2 ) ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation TimeInterval EnglishLanguage "An interval of time. Note that a &%TimeInterval has both an extent and a location on the universal timeline. Note too that a &%TimeInterval has no gaps, i.e. this class contains only convex time intervals.")
% 0.20/0.50 thf(ax_022,axiom,
% 0.20/0.50 ! [INTERVAL1: $i,INTERVAL2: $i] :
% 0.20/0.50 ( ( ( ( lBeginFn_THFTYPE_IiiI @ INTERVAL1 )
% 0.20/0.50 = ( lBeginFn_THFTYPE_IiiI @ INTERVAL2 ) )
% 0.20/0.50 & ( ( lEndFn_THFTYPE_IiiI @ INTERVAL1 )
% 0.20/0.50 = ( lEndFn_THFTYPE_IiiI @ INTERVAL2 ) ) )
% 0.20/0.50 => ( INTERVAL1 = INTERVAL2 ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_023,axiom,
% 0.20/0.50 ! [SITUATION: $o,TIME2: $i,TIME1: $i] :
% 0.20/0.50 ( ( ( holdsDuring_THFTYPE_IiooI @ TIME1 @ SITUATION )
% 0.20/0.50 & ( temporalPart_THFTYPE_IiioI @ TIME2 @ TIME1 ) )
% 0.20/0.50 => ( holdsDuring_THFTYPE_IiooI @ TIME2 @ SITUATION ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation BinaryPredicate EnglishLanguage "A &%Predicate relating two items - its valence is two.")
% 0.20/0.50 thf(ax_024,axiom,
% 0.20/0.50 ! [REL2: $i,CLASS1: $i,REL1: $i] :
% 0.20/0.50 ( ( ( subrelation_THFTYPE_IiioI @ REL1 @ REL2 )
% 0.20/0.50 & ( range_THFTYPE_IiioI @ REL2 @ CLASS1 ) )
% 0.20/0.50 => ( range_THFTYPE_IiioI @ REL1 @ CLASS1 ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation MeasureFn EnglishLanguage "This &%BinaryFunction maps a &%RealNumber and a &%UnitOfMeasure to that &%Number of units. It is used to express `measured' instances of &%PhysicalQuantity. Example: the concept of three meters is represented as (&%MeasureFn 3 &%Meter).")
% 0.20/0.50 %KIF documentation:(documentation subclass EnglishLanguage "(&%subclass ?CLASS1 ?CLASS2) means that ?CLASS1 is a subclass of ?CLASS2, i.e. every instance of ?CLASS1 is also an instance of ?CLASS2. A class may have multiple superclasses and subclasses.")
% 0.20/0.50 %KIF documentation:(documentation part EnglishLanguage "The basic mereological relation. All other mereological relations are defined in terms of this one. (&%part ?PART ?WHOLE) simply means that the &%Object ?PART is part of the &%Object ?WHOLE. Note that, since &%part is a &%ReflexiveRelation, every &%Object is a part of itself.")
% 0.20/0.50 thf(ax_025,axiom,
% 0.20/0.50 holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i ) @ ( parent_THFTYPE_IiioI @ lMary_THFTYPE_i @ lAnna_THFTYPE_i ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation WhenFn EnglishLanguage "A &%UnaryFunction that maps an &%Object or &%Process to the exact &%TimeInterval during which it exists. Note that, for every &%TimePoint ?TIME outside of the &%TimeInterval (WhenFn ?THING), (time ?THING ?TIME) does not hold.")
% 0.20/0.50 %KIF documentation:(documentation documentation EnglishLanguage "A relation between objects in the domain of discourse and strings of natural language text stated in a particular &%HumanLanguage. The domain of &%documentation is not constants (names), but the objects themselves. This means that one does not quote the names when associating them with their documentation.")
% 0.20/0.50 thf(ax_026,axiom,
% 0.20/0.50 ! [NUMBER: $i,CLASS1: $i,REL: $i,CLASS2: $i] :
% 0.20/0.50 ( ( ( domain_THFTYPE_IiiioI @ REL @ NUMBER @ CLASS1 )
% 0.20/0.50 & ( domain_THFTYPE_IiiioI @ REL @ NUMBER @ CLASS2 ) )
% 0.20/0.50 => ( ( subclass_THFTYPE_IiioI @ CLASS1 @ CLASS2 )
% 0.20/0.50 | ( subclass_THFTYPE_IiioI @ CLASS2 @ CLASS1 ) ) ) ).
% 0.20/0.50
% 0.20/0.50 thf(ax_027,axiom,
% 0.20/0.50 ! [NUMBER: $i,PRED1: $i,CLASS1: $i,PRED2: $i] :
% 0.20/0.50 ( ( ( subrelation_THFTYPE_IiioI @ PRED1 @ PRED2 )
% 0.20/0.50 & ( domain_THFTYPE_IiiioI @ PRED2 @ NUMBER @ CLASS1 ) )
% 0.20/0.50 => ( domain_THFTYPE_IiiioI @ PRED1 @ NUMBER @ CLASS1 ) ) ).
% 0.20/0.50
% 0.20/0.50 %KIF documentation:(documentation located EnglishLanguage "(&%located ?PHYS ?OBJ) means that ?PHYS is &%partlyLocated at ?OBJ, and there is no &%part or &%subProcess of ?PHYS that is not &%located at ?OBJ.")
% 0.20/0.50 %KIF documentation:(documentation agent EnglishLanguage "(&%agent ?PROCESS ?AGENT) means that ?AGENT is an active determinant, either animate or inanimate, of the &%Process ?PROCESS, with or without voluntary intention. For example, Eve is an &%agent in the following proposition: Eve bit an apple.")
% 0.20/0.50 thf(ax_028,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ meetsTemporally_THFTYPE_IiioI @ lTemporalRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_029,axiom,
% 0.20/0.50 domain_THFTYPE_IiiioI @ patient_THFTYPE_i @ n1_THFTYPE_i @ lProcess_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_030,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ temporalPart_THFTYPE_IiioI @ lTemporalRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_031,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ range_THFTYPE_IiioI @ lAsymmetricRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_032,axiom,
% 0.20/0.50 domain_THFTYPE_IIiiIiioI @ lYearFn_THFTYPE_IiiI @ n1_THFTYPE_i @ lInteger_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_033,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ range_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_034,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lYearFn_THFTYPE_IiiI @ lUnaryFunction_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_035,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ meetsTemporally_THFTYPE_IiioI @ lAsymmetricRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_036,axiom,
% 0.20/0.50 instance_THFTYPE_IiioI @ lMeasureFn_THFTYPE_i @ lTotalValuedRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_037,axiom,
% 0.20/0.50 domain_THFTYPE_IIiioIiioI @ subProcess_THFTYPE_IiioI @ n1_THFTYPE_i @ lProcess_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_038,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lEndFn_THFTYPE_IiiI @ lTotalValuedRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_039,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ temporalPart_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_040,axiom,
% 0.20/0.50 domain_THFTYPE_IIiioIiioI @ meetsTemporally_THFTYPE_IiioI @ n2_THFTYPE_i @ lTimeInterval_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_041,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ subProcess_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_042,axiom,
% 0.20/0.50 domain_THFTYPE_IIiioIiioI @ meetsTemporally_THFTYPE_IiioI @ n1_THFTYPE_i @ lTimeInterval_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_043,axiom,
% 0.20/0.50 instance_THFTYPE_IIiooIioI @ holdsDuring_THFTYPE_IiooI @ lAsymmetricRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_044,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lBeginFn_THFTYPE_IiiI @ lUnaryFunction_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_045,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ subrelation_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_046,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lBeginFn_THFTYPE_IiiI @ lTotalValuedRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_047,axiom,
% 0.20/0.50 domain_THFTYPE_IIiioIiioI @ subProcess_THFTYPE_IiioI @ n2_THFTYPE_i @ lProcess_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_048,axiom,
% 0.20/0.50 domain_THFTYPE_IiiioI @ agent_THFTYPE_i @ n1_THFTYPE_i @ lProcess_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_049,axiom,
% 0.20/0.50 domain_THFTYPE_IIiiIiioI @ lEndFn_THFTYPE_IiiI @ n1_THFTYPE_i @ lTimeInterval_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_050,axiom,
% 0.20/0.50 instance_THFTYPE_IiioI @ equal_THFTYPE_i @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_051,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ meetsTemporally_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_052,axiom,
% 0.20/0.50 instance_THFTYPE_IiioI @ lWhenFn_THFTYPE_i @ lTotalValuedRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_053,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ subclass_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_054,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lBeginFn_THFTYPE_IiiI @ lTemporalRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_055,axiom,
% 0.20/0.50 domain_THFTYPE_IIiiIiioI @ lBeginFn_THFTYPE_IiiI @ n1_THFTYPE_i @ lTimeInterval_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_056,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lEndFn_THFTYPE_IiiI @ lUnaryFunction_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_057,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lYearFn_THFTYPE_IiiI @ lTemporalRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_058,axiom,
% 0.20/0.50 instance_THFTYPE_IiioI @ attribute_THFTYPE_i @ lAsymmetricRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_059,axiom,
% 0.20/0.50 instance_THFTYPE_IIiioIioI @ instance_THFTYPE_IiioI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_060,axiom,
% 0.20/0.50 instance_THFTYPE_IiioI @ lWhenFn_THFTYPE_i @ lUnaryFunction_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_061,axiom,
% 0.20/0.50 instance_THFTYPE_IIiooIioI @ holdsDuring_THFTYPE_IiooI @ lBinaryPredicate_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_062,axiom,
% 0.20/0.50 instance_THFTYPE_IiioI @ lWhenFn_THFTYPE_i @ lTemporalRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 thf(ax_063,axiom,
% 0.20/0.50 instance_THFTYPE_IIiiIioI @ lEndFn_THFTYPE_IiiI @ lTemporalRelation_THFTYPE_i ).
% 0.20/0.50
% 0.20/0.50 %----The translated conjecture
% 0.20/0.50 thf(con,conjecture,
% 0.20/0.50 ? [R: $i > $i > $o] :
% 0.20/0.50 ( holdsDuring_THFTYPE_IiooI @ ( lYearFn_THFTYPE_IiiI @ n2009_THFTYPE_i )
% 0.20/0.50 @ ( ( R @ lSue_THFTYPE_i @ lBill_THFTYPE_i )
% 0.20/0.50 & ( R @ lMary_THFTYPE_i @ lBill_THFTYPE_i )
% 0.20/0.50 & ( (~)
% 0.20/0.50 @ ! [A: $i,B: $i] : ( R @ A @ B ) ) ) ) ).
% 0.20/0.52
% 0.20/0.52 %------------------------------------------------------------------------------
% 0.20/0.52 ------- convert to smt2 : /export/starexec/sandbox/tmp/tmp.ihG505dDzZ/cvc5---1.0.5_11734.p...
% 0.20/0.52 (declare-sort $$unsorted 0)
% 0.20/0.52 (declare-sort tptp.num 0)
% 0.20/0.52 (declare-fun tptp.agent_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.attribute_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.domain_THFTYPE_IIiiIiioI ((-> $$unsorted $$unsorted) $$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.domain_THFTYPE_IIiioIiioI ((-> $$unsorted $$unsorted Bool) $$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.domain_THFTYPE_IiiioI ($$unsorted $$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.equal_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.holdsDuring_THFTYPE_IiooI ($$unsorted Bool) Bool)
% 0.20/0.52 (declare-fun tptp.instance_THFTYPE_IIiiIioI ((-> $$unsorted $$unsorted) $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.instance_THFTYPE_IIiioIioI ((-> $$unsorted $$unsorted Bool) $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.instance_THFTYPE_IIiooIioI ((-> $$unsorted Bool Bool) $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.instance_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.lAnna_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lAsymmetricRelation_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lBeginFn_THFTYPE_IiiI ($$unsorted) $$unsorted)
% 0.20/0.52 (declare-fun tptp.lBen_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lBill_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lBinaryPredicate_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lBob_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lEndFn_THFTYPE_IiiI ($$unsorted) $$unsorted)
% 0.20/0.52 (declare-fun tptp.lInteger_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lMary_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lMeasureFn_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lProcess_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lSue_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lTemporalRelation_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lTimeInterval_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lTotalValuedRelation_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lUnaryFunction_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lWhenFn_THFTYPE_IiiI ($$unsorted) $$unsorted)
% 0.20/0.52 (declare-fun tptp.lWhenFn_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.lYearFn_THFTYPE_IiiI ($$unsorted) $$unsorted)
% 0.20/0.52 (declare-fun tptp.likes_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.located_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.meetsTemporally_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.n1_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.n2009_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.n2_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.parent_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.part_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.patient_THFTYPE_i () $$unsorted)
% 0.20/0.52 (declare-fun tptp.range_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.subProcess_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.subclass_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.subrelation_THFTYPE_IIioIIioIoI ((-> $$unsorted Bool) (-> $$unsorted Bool)) Bool)
% 0.20/0.52 (declare-fun tptp.subrelation_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (declare-fun tptp.temporalPart_THFTYPE_IiioI ($$unsorted $$unsorted) Bool)
% 0.20/0.52 (assert (forall ((SUBPROC $$unsorted) (PROC $$unsorted)) (=> (@ (@ tptp.subProcess_THFTYPE_IiioI SUBPROC) PROC) (forall ((REGION $$unsorted)) (=> (@ (@ tptp.located_THFTYPE_IiioI PROC) REGION) (@ (@ tptp.located_THFTYPE_IiioI SUBPROC) REGION))))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.parent_THFTYPE_IiioI tptp.lMary_THFTYPE_i) tptp.lBen_THFTYPE_i)))
% 0.20/0.52 (assert (forall ((X $$unsorted) (Y $$unsorted) (Z $$unsorted)) (let ((_let_1 (@ tptp.instance_THFTYPE_IiioI Z))) (=> (and (@ (@ tptp.subclass_THFTYPE_IiioI X) Y) (@ _let_1 X)) (@ _let_1 Y)))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.likes_THFTYPE_IiioI tptp.lSue_THFTYPE_i) tptp.lBill_THFTYPE_i)))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.likes_THFTYPE_IiioI tptp.lSue_THFTYPE_i) tptp.lBill_THFTYPE_i)))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.likes_THFTYPE_IiioI tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i)))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.likes_THFTYPE_IiioI tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i)))
% 0.20/0.52 (assert (forall ((CLASS1 $$unsorted) (CLASS2 $$unsorted)) (=> (= CLASS1 CLASS2) (forall ((THING $$unsorted)) (let ((_let_1 (@ tptp.instance_THFTYPE_IiioI THING))) (= (@ _let_1 CLASS1) (@ _let_1 CLASS2)))))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (not (@ (@ tptp.likes_THFTYPE_IiioI tptp.lSue_THFTYPE_i) tptp.lMary_THFTYPE_i))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (not (@ (@ tptp.likes_THFTYPE_IiioI tptp.lSue_THFTYPE_i) tptp.lMary_THFTYPE_i))))
% 0.20/0.52 (assert (forall ((REL2 (-> $$unsorted Bool)) (ROW $$unsorted) (REL1 (-> $$unsorted Bool))) (=> (and (@ (@ tptp.subrelation_THFTYPE_IIioIIioIoI REL1) REL2) (@ REL1 ROW)) (@ REL2 ROW))))
% 0.20/0.52 (assert (forall ((TIME $$unsorted) (SITUATION Bool)) (let ((_let_1 (@ tptp.holdsDuring_THFTYPE_IiooI TIME))) (=> (@ _let_1 (not SITUATION)) (not (@ _let_1 SITUATION))))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.parent_THFTYPE_IiioI tptp.lSue_THFTYPE_i) tptp.lAnna_THFTYPE_i)))
% 0.20/0.52 (assert (forall ((OBJ1 $$unsorted) (OBJ2 $$unsorted)) (=> (@ (@ tptp.located_THFTYPE_IiioI OBJ1) OBJ2) (forall ((SUB $$unsorted)) (=> (@ (@ tptp.part_THFTYPE_IiioI SUB) OBJ1) (@ (@ tptp.located_THFTYPE_IiioI SUB) OBJ2))))))
% 0.20/0.52 (assert (forall ((THING2 $$unsorted) (THING1 $$unsorted)) (=> (= THING1 THING2) (forall ((CLASS $$unsorted)) (= (@ (@ tptp.instance_THFTYPE_IiioI THING1) CLASS) (@ (@ tptp.instance_THFTYPE_IiioI THING2) CLASS))))))
% 0.20/0.52 (assert (forall ((CLASS1 $$unsorted) (REL $$unsorted) (CLASS2 $$unsorted)) (let ((_let_1 (@ tptp.range_THFTYPE_IiioI REL))) (=> (and (@ _let_1 CLASS1) (@ _let_1 CLASS2)) (or (@ (@ tptp.subclass_THFTYPE_IiioI CLASS1) CLASS2) (@ (@ tptp.subclass_THFTYPE_IiioI CLASS2) CLASS1))))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.likes_THFTYPE_IiioI tptp.lBob_THFTYPE_i) tptp.lBill_THFTYPE_i)))
% 0.20/0.52 (assert (@ (@ tptp.range_THFTYPE_IiioI tptp.lWhenFn_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i))
% 0.20/0.52 (assert (forall ((SUBPROC $$unsorted) (PROC $$unsorted)) (=> (@ (@ tptp.subProcess_THFTYPE_IiioI SUBPROC) PROC) (@ (@ tptp.temporalPart_THFTYPE_IiioI (@ tptp.lWhenFn_THFTYPE_IiiI SUBPROC)) (@ tptp.lWhenFn_THFTYPE_IiiI PROC)))))
% 0.20/0.52 (assert (forall ((OBJ $$unsorted) (PROCESS $$unsorted)) (=> (@ (@ tptp.located_THFTYPE_IiioI PROCESS) OBJ) (forall ((SUB $$unsorted)) (=> (@ (@ tptp.subProcess_THFTYPE_IiioI SUB) PROCESS) (@ (@ tptp.located_THFTYPE_IiioI SUB) OBJ))))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.parent_THFTYPE_IiioI tptp.lSue_THFTYPE_i) tptp.lBen_THFTYPE_i)))
% 0.20/0.52 (assert (forall ((INTERVAL1 $$unsorted) (INTERVAL2 $$unsorted)) (= (@ (@ tptp.meetsTemporally_THFTYPE_IiioI INTERVAL1) INTERVAL2) (= (@ tptp.lEndFn_THFTYPE_IiiI INTERVAL1) (@ tptp.lBeginFn_THFTYPE_IiiI INTERVAL2)))))
% 0.20/0.52 (assert (forall ((INTERVAL1 $$unsorted) (INTERVAL2 $$unsorted)) (=> (and (= (@ tptp.lBeginFn_THFTYPE_IiiI INTERVAL1) (@ tptp.lBeginFn_THFTYPE_IiiI INTERVAL2)) (= (@ tptp.lEndFn_THFTYPE_IiiI INTERVAL1) (@ tptp.lEndFn_THFTYPE_IiiI INTERVAL2))) (= INTERVAL1 INTERVAL2))))
% 0.20/0.52 (assert (forall ((SITUATION Bool) (TIME2 $$unsorted) (TIME1 $$unsorted)) (=> (and (@ (@ tptp.holdsDuring_THFTYPE_IiooI TIME1) SITUATION) (@ (@ tptp.temporalPart_THFTYPE_IiioI TIME2) TIME1)) (@ (@ tptp.holdsDuring_THFTYPE_IiooI TIME2) SITUATION))))
% 0.20/0.52 (assert (forall ((REL2 $$unsorted) (CLASS1 $$unsorted) (REL1 $$unsorted)) (=> (and (@ (@ tptp.subrelation_THFTYPE_IiioI REL1) REL2) (@ (@ tptp.range_THFTYPE_IiioI REL2) CLASS1)) (@ (@ tptp.range_THFTYPE_IiioI REL1) CLASS1))))
% 0.20/0.52 (assert (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (@ (@ tptp.parent_THFTYPE_IiioI tptp.lMary_THFTYPE_i) tptp.lAnna_THFTYPE_i)))
% 0.20/0.52 (assert (forall ((NUMBER $$unsorted) (CLASS1 $$unsorted) (REL $$unsorted) (CLASS2 $$unsorted)) (let ((_let_1 (@ (@ tptp.domain_THFTYPE_IiiioI REL) NUMBER))) (=> (and (@ _let_1 CLASS1) (@ _let_1 CLASS2)) (or (@ (@ tptp.subclass_THFTYPE_IiioI CLASS1) CLASS2) (@ (@ tptp.subclass_THFTYPE_IiioI CLASS2) CLASS1))))))
% 0.20/0.52 (assert (forall ((NUMBER $$unsorted) (PRED1 $$unsorted) (CLASS1 $$unsorted) (PRED2 $$unsorted)) (=> (and (@ (@ tptp.subrelation_THFTYPE_IiioI PRED1) PRED2) (@ (@ (@ tptp.domain_THFTYPE_IiiioI PRED2) NUMBER) CLASS1)) (@ (@ (@ tptp.domain_THFTYPE_IiiioI PRED1) NUMBER) CLASS1))))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.meetsTemporally_THFTYPE_IiioI) tptp.lTemporalRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IiiioI tptp.patient_THFTYPE_i) tptp.n1_THFTYPE_i) tptp.lProcess_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.temporalPart_THFTYPE_IiioI) tptp.lTemporalRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.range_THFTYPE_IiioI) tptp.lAsymmetricRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiiIiioI tptp.lYearFn_THFTYPE_IiiI) tptp.n1_THFTYPE_i) tptp.lInteger_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.range_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lYearFn_THFTYPE_IiiI) tptp.lUnaryFunction_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.meetsTemporally_THFTYPE_IiioI) tptp.lAsymmetricRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IiioI tptp.lMeasureFn_THFTYPE_i) tptp.lTotalValuedRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiioIiioI tptp.subProcess_THFTYPE_IiioI) tptp.n1_THFTYPE_i) tptp.lProcess_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lEndFn_THFTYPE_IiiI) tptp.lTotalValuedRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.temporalPart_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiioIiioI tptp.meetsTemporally_THFTYPE_IiioI) tptp.n2_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.subProcess_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiioIiioI tptp.meetsTemporally_THFTYPE_IiioI) tptp.n1_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiooIioI tptp.holdsDuring_THFTYPE_IiooI) tptp.lAsymmetricRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lBeginFn_THFTYPE_IiiI) tptp.lUnaryFunction_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.subrelation_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lBeginFn_THFTYPE_IiiI) tptp.lTotalValuedRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiioIiioI tptp.subProcess_THFTYPE_IiioI) tptp.n2_THFTYPE_i) tptp.lProcess_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IiiioI tptp.agent_THFTYPE_i) tptp.n1_THFTYPE_i) tptp.lProcess_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiiIiioI tptp.lEndFn_THFTYPE_IiiI) tptp.n1_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IiioI tptp.equal_THFTYPE_i) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.meetsTemporally_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IiioI tptp.lWhenFn_THFTYPE_i) tptp.lTotalValuedRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.subclass_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lBeginFn_THFTYPE_IiiI) tptp.lTemporalRelation_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ (@ tptp.domain_THFTYPE_IIiiIiioI tptp.lBeginFn_THFTYPE_IiiI) tptp.n1_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i))
% 0.20/0.52 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lEndFn_THFTYPE_IiiI) tptp.lUnaryFunction_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lYearFn_THFTYPE_IiiI) tptp.lTemporalRelation_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IiioI tptp.attribute_THFTYPE_i) tptp.lAsymmetricRelation_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.instance_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IiioI tptp.lWhenFn_THFTYPE_i) tptp.lUnaryFunction_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IIiooIioI tptp.holdsDuring_THFTYPE_IiooI) tptp.lBinaryPredicate_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IiioI tptp.lWhenFn_THFTYPE_i) tptp.lTemporalRelation_THFTYPE_i))
% 0.20/0.59 (assert (@ (@ tptp.instance_THFTYPE_IIiiIioI tptp.lEndFn_THFTYPE_IiiI) tptp.lTemporalRelation_THFTYPE_i))
% 0.20/0.59 (assert (not (exists ((R (-> $$unsorted $$unsorted Bool))) (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (and (@ (@ R tptp.lSue_THFTYPE_i) tptp.lBill_THFTYPE_i) (@ (@ R tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i) (not (forall ((A $$unsorted) (B $$unsorted)) (@ (@ R A) B))))))))
% 0.20/0.59 (set-info :filename cvc5---1.0.5_11734)
% 0.20/0.59 (check-sat-assuming ( true ))
% 0.20/0.59 ------- get file name : TPTP file name is CSR130^2
% 0.20/0.59 ------- cvc5-thf : /export/starexec/sandbox/solver/bin/cvc5---1.0.5_11734.smt2...
% 0.20/0.59 --- Run --ho-elim --full-saturate-quant at 10...
% 0.20/0.59 % SZS status Theorem for CSR130^2
% 0.20/0.59 % SZS output start Proof for CSR130^2
% 0.20/0.59 (
% 0.20/0.59 (let ((_let_1 (not (exists ((R (-> $$unsorted $$unsorted Bool))) (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (and (@ (@ R tptp.lSue_THFTYPE_i) tptp.lBill_THFTYPE_i) (@ (@ R tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i) (not (forall ((A $$unsorted) (B $$unsorted)) (@ (@ R A) B))))))))) (let ((_let_2 (@ tptp.instance_THFTYPE_IIiiIioI tptp.lEndFn_THFTYPE_IiiI))) (let ((_let_3 (@ tptp.instance_THFTYPE_IiioI tptp.lWhenFn_THFTYPE_i))) (let ((_let_4 (@ tptp.instance_THFTYPE_IIiooIioI tptp.holdsDuring_THFTYPE_IiooI))) (let ((_let_5 (@ tptp.instance_THFTYPE_IIiiIioI tptp.lYearFn_THFTYPE_IiiI))) (let ((_let_6 (@ tptp.instance_THFTYPE_IIiiIioI tptp.lBeginFn_THFTYPE_IiiI))) (let ((_let_7 (@ tptp.instance_THFTYPE_IIiioIioI tptp.meetsTemporally_THFTYPE_IiioI))) (let ((_let_8 (@ tptp.domain_THFTYPE_IIiioIiioI tptp.subProcess_THFTYPE_IiioI))) (let ((_let_9 (@ tptp.domain_THFTYPE_IIiioIiioI tptp.meetsTemporally_THFTYPE_IiioI))) (let ((_let_10 (@ tptp.instance_THFTYPE_IIiioIioI tptp.temporalPart_THFTYPE_IiioI))) (let ((_let_11 (@ tptp.instance_THFTYPE_IIiioIioI tptp.range_THFTYPE_IiioI))) (let ((_let_12 (@ tptp.parent_THFTYPE_IiioI tptp.lMary_THFTYPE_i))) (let ((_let_13 (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)))) (let ((_let_14 (@ tptp.parent_THFTYPE_IiioI tptp.lSue_THFTYPE_i))) (let ((_let_15 (forall ((TIME $$unsorted) (SITUATION Bool)) (let ((_let_1 (@ tptp.holdsDuring_THFTYPE_IiooI TIME))) (=> (@ _let_1 (not SITUATION)) (not (@ _let_1 SITUATION))))))) (let ((_let_16 (@ tptp.likes_THFTYPE_IiioI tptp.lSue_THFTYPE_i))) (let ((_let_17 (@ _let_13 (not (@ _let_16 tptp.lMary_THFTYPE_i))))) (let ((_let_18 (@ _let_13 (@ (@ tptp.likes_THFTYPE_IiioI tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i)))) (let ((_let_19 (@ _let_13 (@ _let_16 tptp.lBill_THFTYPE_i)))) (let ((_let_20 (@ _let_13 (@ _let_12 tptp.lBen_THFTYPE_i)))) (let ((_let_21 (ho_8 k_7 tptp.n2009_THFTYPE_i))) (let ((_let_22 (ho_10 k_9 _let_21))) (let ((_let_23 (ho_11 _let_22 BOOLEAN_TERM_VARIABLE_2041))) (let ((_let_24 (ho_11 _let_22 BOOLEAN_TERM_VARIABLE_3412))) (let ((_let_25 (APPLY_UF ho_11))) (let ((_let_26 (ho_4 (ho_3 k_6 tptp.lMary_THFTYPE_i) tptp.lBen_THFTYPE_i))) (let ((_let_27 (REFL :args (_let_22)))) (let ((_let_28 (EQ_RESOLVE (ASSUME :args (_let_20)) (TRANS (PREPROCESS :args ((= _let_20 (ho_11 _let_22 _let_26)))) (CONG _let_27 (MACRO_SR_PRED_INTRO :args ((= _let_26 BOOLEAN_TERM_VARIABLE_2041))) :args _let_25))))) (let ((_let_29 (forall ((BOUND_VARIABLE_1501 |u_(-> $$unsorted $$unsorted Bool)|)) (not (ho_11 (ho_10 k_9 (ho_8 k_7 tptp.n2009_THFTYPE_i)) (and (ho_4 (ho_3 BOUND_VARIABLE_1501 tptp.lSue_THFTYPE_i) tptp.lBill_THFTYPE_i) (ho_4 (ho_3 BOUND_VARIABLE_1501 tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i) (not (forall ((A $$unsorted) (B $$unsorted)) (ho_4 (ho_3 BOUND_VARIABLE_1501 A) B))))))))) (let ((_let_30 (not _let_24))) (let ((_let_31 (EQ_RESOLVE (ASSUME :args (_let_1)) (TRANS (MACRO_SR_EQ_INTRO :args (_let_1 SB_DEFAULT SBA_FIXPOINT)) (PREPROCESS :args ((= (forall ((R (-> $$unsorted $$unsorted Bool))) (not (@ (@ tptp.holdsDuring_THFTYPE_IiooI (@ tptp.lYearFn_THFTYPE_IiiI tptp.n2009_THFTYPE_i)) (and (@ (@ R tptp.lSue_THFTYPE_i) tptp.lBill_THFTYPE_i) (@ (@ R tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i) (not (forall ((A $$unsorted) (B $$unsorted)) (@ (@ R A) B))))))) _let_29))))))) (let ((_let_32 (=>))) (let ((_let_33 (not))) (let ((_let_34 (forall ((A $$unsorted) (B $$unsorted)) (ho_4 (ho_3 k_14 A) B)))) (let ((_let_35 (not _let_34))) (let ((_let_36 (ho_4 (ho_3 k_14 tptp.lMary_THFTYPE_i) tptp.lBill_THFTYPE_i))) (let ((_let_37 (ho_3 k_14 tptp.lSue_THFTYPE_i))) (let ((_let_38 (ho_4 _let_37 tptp.lBill_THFTYPE_i))) (let ((_let_39 (and _let_38 _let_36 _let_35))) (let ((_let_40 (MACRO_SR_PRED_INTRO :args ((= _let_39 BOOLEAN_TERM_VARIABLE_3412))))) (let ((_let_41 (_let_29))) (let ((_let_42 (MACRO_RESOLUTION_TRUST (IMPLIES_ELIM (EQ_RESOLVE (SCOPE (INSTANTIATE _let_31 :args (k_14 QUANTIFIERS_INST_E_MATCHING_SIMPLE ((ho_3 BOUND_VARIABLE_1501 tptp.lSue_THFTYPE_i)))) :args _let_41) (CONG (REFL :args _let_41) (CONG (CONG _let_27 _let_40 :args _let_25) :args _let_33) :args _let_32))) _let_31 :args (_let_30 false _let_29)))) (let ((_let_43 (ho_11 _let_22 BOOLEAN_TERM_VARIABLE_2070))) (let ((_let_44 (ho_11 _let_22 BOOLEAN_TERM_VARIABLE_3289))) (let ((_let_45 (ho_4 _let_37 tptp.lMary_THFTYPE_i))) (let ((_let_46 (ho_11 _let_22 BOOLEAN_TERM_VARIABLE_2060))) (let ((_let_47 (ho_11 _let_22 BOOLEAN_TERM_VARIABLE_2051))) (let ((_let_48 (not BOOLEAN_TERM_VARIABLE_2041))) (let ((_let_49 (SYMM (MACRO_SR_PRED_INTRO :args ((= BOOLEAN_TERM_VARIABLE_3289 _let_48)))))) (let ((_let_50 (not BOOLEAN_TERM_VARIABLE_3412))) (let ((_let_51 (not _let_23))) (let ((_let_52 (or))) (let ((_let_53 (MACRO_SR_PRED_INTRO :args ((= (not _let_30) _let_24))))) (let ((_let_54 (_let_50))) (let ((_let_55 (REFL :args (_let_51)))) (let ((_let_56 (_let_48))) (let ((_let_57 (TRUE_INTRO _let_28))) (let ((_let_58 (ASSUME :args (BOOLEAN_TERM_VARIABLE_2041)))) (let ((_let_59 (ASSUME :args (BOOLEAN_TERM_VARIABLE_3412)))) (let ((_let_60 (ASSUME :args (_let_30)))) (let ((_let_61 (SYMM (FALSE_INTRO _let_60)))) (let ((_let_62 (not _let_39))) (let ((_let_63 (not _let_45))) (let ((_let_64 (MACRO_SR_PRED_INTRO :args ((= _let_63 BOOLEAN_TERM_VARIABLE_2070))))) (let ((_let_65 (EQ_RESOLVE (ASSUME :args (_let_17)) (TRANS (PREPROCESS :args ((= _let_17 (ho_11 _let_22 _let_63)))) (CONG _let_27 _let_64 :args _let_25))))) (let ((_let_66 (not _let_44))) (let ((_let_67 (or _let_66 _let_51))) (let ((_let_68 (forall ((TIME $$unsorted) (SITUATION Bool)) (let ((_let_1 (ho_10 k_9 TIME))) (or (not (ho_11 _let_1 (not SITUATION))) (not (ho_11 _let_1 SITUATION))))))) (let ((_let_69 (EQ_RESOLVE (ASSUME :args (_let_15)) (TRANS (MACRO_SR_EQ_INTRO :args (_let_15 SB_DEFAULT SBA_FIXPOINT)) (PREPROCESS :args ((= (forall ((TIME $$unsorted) (SITUATION Bool)) (let ((_let_1 (@ tptp.holdsDuring_THFTYPE_IiooI TIME))) (or (not (@ _let_1 (not SITUATION))) (not (@ _let_1 SITUATION))))) _let_68))))))) (let ((_let_70 (_let_68))) (let ((_let_71 (MACRO_RESOLUTION_TRUST (REORDERING (CNF_OR_POS :args (_let_67)) :args ((or _let_51 _let_66 (not _let_67)))) _let_28 (MACRO_RESOLUTION_TRUST (IMPLIES_ELIM (EQ_RESOLVE (SCOPE (INSTANTIATE _let_69 :args (_let_21 BOOLEAN_TERM_VARIABLE_2041 QUANTIFIERS_INST_E_MATCHING ((not (= (ho_11 (ho_10 k_9 TIME) SITUATION) false))))) :args _let_70) (CONG (REFL :args _let_70) (CONG (CONG (CONG _let_27 _let_49 :args _let_25) :args _let_33) _let_55 :args _let_52) :args _let_32))) _let_69 :args (_let_67 false _let_68)) :args (_let_66 false _let_23 false _let_67)))) (let ((_let_72 (not _let_43))) (let ((_let_73 (not BOOLEAN_TERM_VARIABLE_3289))) (let ((_let_74 (MACRO_SR_PRED_INTRO :args ((= (not _let_73) BOOLEAN_TERM_VARIABLE_3289))))) (let ((_let_75 (MACRO_SR_PRED_INTRO :args ((= (not _let_66) _let_44))))) (let ((_let_76 (not BOOLEAN_TERM_VARIABLE_2070))) (let ((_let_77 (ASSUME :args (_let_66)))) (let ((_let_78 (FALSE_INTRO _let_77))) (let ((_let_79 (_let_73))) (let ((_let_80 (ASSUME :args _let_79))) (let ((_let_81 (SYMM (FALSE_INTRO _let_80)))) (let ((_let_82 (ASSUME :args (_let_76)))) (let ((_let_83 (_let_34))) (let ((_let_84 (MACRO_SR_PRED_INTRO :args ((= _let_36 BOOLEAN_TERM_VARIABLE_2060))))) (let ((_let_85 (EQ_RESOLVE (ASSUME :args (_let_18)) (TRANS (PREPROCESS :args ((= _let_18 (ho_11 _let_22 _let_36)))) (CONG _let_27 _let_84 :args _let_25))))) (let ((_let_86 (not _let_46))) (let ((_let_87 (not BOOLEAN_TERM_VARIABLE_2060))) (let ((_let_88 (ASSUME :args (_let_87)))) (let ((_let_89 (not _let_36))) (let ((_let_90 (not _let_38))) (let ((_let_91 (_let_39))) (let ((_let_92 (SYMM (MACRO_SR_PRED_INTRO :args ((= BOOLEAN_TERM_VARIABLE_2051 _let_38)))))) (let ((_let_93 (EQ_RESOLVE (ASSUME :args (_let_19)) (TRANS (PREPROCESS :args ((= _let_19 (ho_11 _let_22 _let_38)))) (CONG _let_27 _let_92 :args _let_25))))) (let ((_let_94 (not _let_47))) (let ((_let_95 (not BOOLEAN_TERM_VARIABLE_2051))) (let ((_let_96 (REFL :args (_let_94)))) (let ((_let_97 (_let_95))) (let ((_let_98 (ASSUME :args _let_97))) (let ((_let_99 (SYMM (TRUE_INTRO _let_93)))) (let ((_let_100 (MACRO_RESOLUTION_TRUST (REORDERING (EQ_RESOLVE (NOT_AND (MACRO_SR_PRED_TRANSFORM (SCOPE (AND_INTRO _let_77 _let_80 _let_98 _let_93) :args (_let_47 _let_95 _let_66 _let_73)) (SCOPE (MACRO_SR_PRED_ELIM (TRANS _let_99 (CONG _let_27 (TRANS (FALSE_INTRO _let_98) _let_81) :args _let_25) _let_78)) :args (_let_66 _let_73 _let_95 _let_47)) :args ((not (and _let_47 _let_95 _let_66 _let_73)) SB_LITERAL))) (CONG _let_96 (MACRO_SR_PRED_INTRO :args ((= (not _let_95) BOOLEAN_TERM_VARIABLE_2051))) _let_75 _let_74 :args _let_52)) :args ((or BOOLEAN_TERM_VARIABLE_2051 _let_94 BOOLEAN_TERM_VARIABLE_3289 _let_44))) _let_71 _let_93 (EQUIV_ELIM2 _let_92) (REORDERING (EQ_RESOLVE (CNF_AND_NEG :args _let_91) (CONG (REFL :args _let_91) (REFL :args (_let_90)) (REFL :args (_let_89)) (MACRO_SR_PRED_INTRO :args ((= (not _let_35) _let_34))) :args _let_52)) :args ((or _let_90 _let_89 _let_34 _let_39))) (EQUIV_ELIM2 _let_84) (REORDERING (EQ_RESOLVE (NOT_AND (MACRO_SR_PRED_TRANSFORM (SCOPE (AND_INTRO _let_77 _let_80 _let_88 _let_85) :args (_let_46 _let_87 _let_66 _let_73)) (SCOPE (MACRO_SR_PRED_ELIM (TRANS (SYMM (TRUE_INTRO _let_85)) (CONG _let_27 (TRANS (FALSE_INTRO _let_88) _let_81) :args _let_25) _let_78)) :args (_let_66 _let_73 _let_87 _let_46)) :args ((not (and _let_46 _let_87 _let_66 _let_73)) SB_LITERAL))) (CONG (REFL :args (_let_86)) (MACRO_SR_PRED_INTRO :args ((= (not _let_87) BOOLEAN_TERM_VARIABLE_2060))) _let_75 _let_74 :args _let_52)) :args ((or BOOLEAN_TERM_VARIABLE_2060 _let_86 BOOLEAN_TERM_VARIABLE_3289 _let_44))) _let_71 _let_85 (REORDERING (IMPLIES_ELIM (SCOPE (INSTANTIATE (ASSUME :args _let_83) :args (tptp.lSue_THFTYPE_i tptp.lMary_THFTYPE_i QUANTIFIERS_INST_CBQI_CONFLICT)) :args _let_83)) :args ((or _let_45 _let_35))) (EQUIV_ELIM2 _let_64) (REORDERING (EQ_RESOLVE (NOT_AND (MACRO_SR_PRED_TRANSFORM (SCOPE (AND_INTRO _let_77 _let_80 _let_82 _let_65) :args (_let_43 _let_76 _let_66 _let_73)) (SCOPE (MACRO_SR_PRED_ELIM (TRANS (SYMM (TRUE_INTRO _let_65)) (CONG _let_27 (TRANS (FALSE_INTRO _let_82) _let_81) :args _let_25) _let_78)) :args (_let_66 _let_73 _let_76 _let_43)) :args ((not (and _let_43 _let_76 _let_66 _let_73)) SB_LITERAL))) (CONG (REFL :args (_let_72)) (MACRO_SR_PRED_INTRO :args ((= (not _let_76) BOOLEAN_TERM_VARIABLE_2070))) _let_75 _let_74 :args _let_52)) :args ((or BOOLEAN_TERM_VARIABLE_2070 _let_72 BOOLEAN_TERM_VARIABLE_3289 _let_44))) _let_71 _let_65 (REORDERING (EQUIV_ELIM1 _let_40) :args ((or BOOLEAN_TERM_VARIABLE_3412 _let_62))) (REORDERING (EQ_RESOLVE (NOT_AND (MACRO_SR_PRED_TRANSFORM (SCOPE (AND_INTRO _let_28 _let_58 _let_59 _let_60) :args (BOOLEAN_TERM_VARIABLE_2041 _let_23 BOOLEAN_TERM_VARIABLE_3412 _let_30)) (SCOPE (MACRO_SR_PRED_ELIM (TRANS _let_61 (CONG _let_27 (TRANS (TRUE_INTRO _let_59) (SYMM (TRUE_INTRO _let_58))) :args _let_25) _let_57)) :args (_let_23 BOOLEAN_TERM_VARIABLE_2041 BOOLEAN_TERM_VARIABLE_3412 _let_30)) :args ((not (and BOOLEAN_TERM_VARIABLE_2041 _let_23 BOOLEAN_TERM_VARIABLE_3412 _let_30)) SB_LITERAL))) (CONG (REFL :args _let_56) _let_55 (REFL :args _let_54) _let_53 :args _let_52)) :args ((or _let_51 _let_48 _let_24 _let_50))) _let_42 _let_28 (EQUIV_ELIM2 _let_49) :args (_let_48 true _let_44 false _let_47 true BOOLEAN_TERM_VARIABLE_2051 true _let_38 false _let_36 false BOOLEAN_TERM_VARIABLE_2060 true _let_44 false _let_46 true _let_34 true _let_45 false BOOLEAN_TERM_VARIABLE_2070 true _let_44 false _let_43 true _let_39 true BOOLEAN_TERM_VARIABLE_3412 true _let_24 false _let_23 true BOOLEAN_TERM_VARIABLE_3289)))) (let ((_let_101 (BOOLEAN_TERM_VARIABLE_3289))) (let ((_let_102 (MACRO_SR_PRED_INTRO :args ((= (not _let_48) BOOLEAN_TERM_VARIABLE_2041))))) (let ((_let_103 (ASSUME :args _let_101))) (let ((_let_104 (ASSUME :args (BOOLEAN_TERM_VARIABLE_2051)))) (let ((_let_105 (ASSUME :args _let_56))) (let ((_let_106 (ASSUME :args _let_54))) (SCOPE (SCOPE (MACRO_RESOLUTION_TRUST (REORDERING (EQ_RESOLVE (NOT_AND (MACRO_SR_PRED_TRANSFORM (SCOPE (AND_INTRO _let_28 _let_105 _let_106 _let_60) :args (_let_23 _let_48 _let_30 _let_50)) (SCOPE (MACRO_SR_PRED_ELIM (TRANS _let_61 (CONG _let_27 (TRANS (FALSE_INTRO _let_106) (SYMM (FALSE_INTRO _let_105))) :args _let_25) _let_57)) :args (_let_23 _let_48 _let_50 _let_30)) :args ((not (and _let_23 _let_48 _let_30 _let_50)) SB_LITERAL))) (CONG _let_55 _let_102 _let_53 (MACRO_SR_PRED_INTRO :args ((= (not _let_50) BOOLEAN_TERM_VARIABLE_3412))) :args _let_52)) :args ((or BOOLEAN_TERM_VARIABLE_2041 _let_51 BOOLEAN_TERM_VARIABLE_3412 _let_24))) (MACRO_RESOLUTION_TRUST (EQUIV_ELIM2 _let_40) (MACRO_RESOLUTION_TRUST (REORDERING (CNF_AND_POS :args (_let_39 0)) :args ((or _let_38 _let_62))) (MACRO_RESOLUTION_TRUST (REORDERING (EQUIV_ELIM1 _let_92) :args ((or BOOLEAN_TERM_VARIABLE_2051 _let_90))) (MACRO_RESOLUTION_TRUST (REORDERING (EQ_RESOLVE (NOT_AND (MACRO_SR_PRED_TRANSFORM (SCOPE (AND_INTRO _let_77 _let_103 _let_104 _let_93) :args (BOOLEAN_TERM_VARIABLE_2051 _let_47 BOOLEAN_TERM_VARIABLE_3289 _let_66)) (SCOPE (MACRO_SR_PRED_ELIM (TRANS _let_99 (CONG _let_27 (TRANS (TRUE_INTRO _let_104) (SYMM (TRUE_INTRO _let_103))) :args _let_25) _let_78)) :args (_let_66 BOOLEAN_TERM_VARIABLE_3289 BOOLEAN_TERM_VARIABLE_2051 _let_47)) :args ((not (and BOOLEAN_TERM_VARIABLE_2051 _let_47 BOOLEAN_TERM_VARIABLE_3289 _let_66)) SB_LITERAL))) (CONG (REFL :args _let_97) _let_96 (REFL :args _let_79) _let_75 :args _let_52)) :args ((or _let_94 _let_95 _let_44 _let_73))) _let_93 _let_71 (MACRO_RESOLUTION_TRUST (EQ_RESOLVE (EQUIV_ELIM1 _let_49) (CONG _let_102 (REFL :args _let_101) :args _let_52)) _let_100 :args (BOOLEAN_TERM_VARIABLE_3289 true BOOLEAN_TERM_VARIABLE_2041)) :args (_let_95 false _let_47 true _let_44 false BOOLEAN_TERM_VARIABLE_3289)) :args (_let_90 true BOOLEAN_TERM_VARIABLE_2051)) :args (_let_62 true _let_38)) :args (_let_50 true _let_39)) _let_100 _let_42 _let_28 :args (false true BOOLEAN_TERM_VARIABLE_3412 true BOOLEAN_TERM_VARIABLE_2041 true _let_24 false _let_23)) :args ((forall ((SUBPROC $$unsorted) (PROC $$unsorted)) (=> (@ (@ tptp.subProcess_THFTYPE_IiioI SUBPROC) PROC) (forall ((REGION $$unsorted)) (=> (@ (@ tptp.located_THFTYPE_IiioI PROC) REGION) (@ (@ tptp.located_THFTYPE_IiioI SUBPROC) REGION))))) _let_20 (forall ((X $$unsorted) (Y $$unsorted) (Z $$unsorted)) (let ((_let_1 (@ tptp.instance_THFTYPE_IiioI Z))) (=> (and (@ (@ tptp.subclass_THFTYPE_IiioI X) Y) (@ _let_1 X)) (@ _let_1 Y)))) _let_19 _let_19 _let_18 _let_18 (forall ((CLASS1 $$unsorted) (CLASS2 $$unsorted)) (=> (= CLASS1 CLASS2) (forall ((THING $$unsorted)) (let ((_let_1 (@ tptp.instance_THFTYPE_IiioI THING))) (= (@ _let_1 CLASS1) (@ _let_1 CLASS2)))))) _let_17 _let_17 (forall ((REL2 (-> $$unsorted Bool)) (ROW $$unsorted) (REL1 (-> $$unsorted Bool))) (=> (and (@ (@ tptp.subrelation_THFTYPE_IIioIIioIoI REL1) REL2) (@ REL1 ROW)) (@ REL2 ROW))) _let_15 (@ _let_13 (@ _let_14 tptp.lAnna_THFTYPE_i)) (forall ((OBJ1 $$unsorted) (OBJ2 $$unsorted)) (=> (@ (@ tptp.located_THFTYPE_IiioI OBJ1) OBJ2) (forall ((SUB $$unsorted)) (=> (@ (@ tptp.part_THFTYPE_IiioI SUB) OBJ1) (@ (@ tptp.located_THFTYPE_IiioI SUB) OBJ2))))) (forall ((THING2 $$unsorted) (THING1 $$unsorted)) (=> (= THING1 THING2) (forall ((CLASS $$unsorted)) (= (@ (@ tptp.instance_THFTYPE_IiioI THING1) CLASS) (@ (@ tptp.instance_THFTYPE_IiioI THING2) CLASS))))) (forall ((CLASS1 $$unsorted) (REL $$unsorted) (CLASS2 $$unsorted)) (let ((_let_1 (@ tptp.range_THFTYPE_IiioI REL))) (=> (and (@ _let_1 CLASS1) (@ _let_1 CLASS2)) (or (@ (@ tptp.subclass_THFTYPE_IiioI CLASS1) CLASS2) (@ (@ tptp.subclass_THFTYPE_IiioI CLASS2) CLASS1))))) (@ _let_13 (@ (@ tptp.likes_THFTYPE_IiioI tptp.lBob_THFTYPE_i) tptp.lBill_THFTYPE_i)) (@ (@ tptp.range_THFTYPE_IiioI tptp.lWhenFn_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i) (forall ((SUBPROC $$unsorted) (PROC $$unsorted)) (=> (@ (@ tptp.subProcess_THFTYPE_IiioI SUBPROC) PROC) (@ (@ tptp.temporalPart_THFTYPE_IiioI (@ tptp.lWhenFn_THFTYPE_IiiI SUBPROC)) (@ tptp.lWhenFn_THFTYPE_IiiI PROC)))) (forall ((OBJ $$unsorted) (PROCESS $$unsorted)) (=> (@ (@ tptp.located_THFTYPE_IiioI PROCESS) OBJ) (forall ((SUB $$unsorted)) (=> (@ (@ tptp.subProcess_THFTYPE_IiioI SUB) PROCESS) (@ (@ tptp.located_THFTYPE_IiioI SUB) OBJ))))) (@ _let_13 (@ _let_14 tptp.lBen_THFTYPE_i)) (forall ((INTERVAL1 $$unsorted) (INTERVAL2 $$unsorted)) (= (@ (@ tptp.meetsTemporally_THFTYPE_IiioI INTERVAL1) INTERVAL2) (= (@ tptp.lEndFn_THFTYPE_IiiI INTERVAL1) (@ tptp.lBeginFn_THFTYPE_IiiI INTERVAL2)))) (forall ((INTERVAL1 $$unsorted) (INTERVAL2 $$unsorted)) (=> (and (= (@ tptp.lBeginFn_THFTYPE_IiiI INTERVAL1) (@ tptp.lBeginFn_THFTYPE_IiiI INTERVAL2)) (= (@ tptp.lEndFn_THFTYPE_IiiI INTERVAL1) (@ tptp.lEndFn_THFTYPE_IiiI INTERVAL2))) (= INTERVAL1 INTERVAL2))) (forall ((SITUATION Bool) (TIME2 $$unsorted) (TIME1 $$unsorted)) (=> (and (@ (@ tptp.holdsDuring_THFTYPE_IiooI TIME1) SITUATION) (@ (@ tptp.temporalPart_THFTYPE_IiioI TIME2) TIME1)) (@ (@ tptp.holdsDuring_THFTYPE_IiooI TIME2) SITUATION))) (forall ((REL2 $$unsorted) (CLASS1 $$unsorted) (REL1 $$unsorted)) (=> (and (@ (@ tptp.subrelation_THFTYPE_IiioI REL1) REL2) (@ (@ tptp.range_THFTYPE_IiioI REL2) CLASS1)) (@ (@ tptp.range_THFTYPE_IiioI REL1) CLASS1))) (@ _let_13 (@ _let_12 tptp.lAnna_THFTYPE_i)) (forall ((NUMBER $$unsorted) (CLASS1 $$unsorted) (REL $$unsorted) (CLASS2 $$unsorted)) (let ((_let_1 (@ (@ tptp.domain_THFTYPE_IiiioI REL) NUMBER))) (=> (and (@ _let_1 CLASS1) (@ _let_1 CLASS2)) (or (@ (@ tptp.subclass_THFTYPE_IiioI CLASS1) CLASS2) (@ (@ tptp.subclass_THFTYPE_IiioI CLASS2) CLASS1))))) (forall ((NUMBER $$unsorted) (PRED1 $$unsorted) (CLASS1 $$unsorted) (PRED2 $$unsorted)) (=> (and (@ (@ tptp.subrelation_THFTYPE_IiioI PRED1) PRED2) (@ (@ (@ tptp.domain_THFTYPE_IiiioI PRED2) NUMBER) CLASS1)) (@ (@ (@ tptp.domain_THFTYPE_IiiioI PRED1) NUMBER) CLASS1))) (@ _let_7 tptp.lTemporalRelation_THFTYPE_i) (@ (@ (@ tptp.domain_THFTYPE_IiiioI tptp.patient_THFTYPE_i) tptp.n1_THFTYPE_i) tptp.lProcess_THFTYPE_i) (@ _let_10 tptp.lTemporalRelation_THFTYPE_i) (@ _let_11 tptp.lAsymmetricRelation_THFTYPE_i) (@ (@ (@ tptp.domain_THFTYPE_IIiiIiioI tptp.lYearFn_THFTYPE_IiiI) tptp.n1_THFTYPE_i) tptp.lInteger_THFTYPE_i) (@ _let_11 tptp.lBinaryPredicate_THFTYPE_i) (@ _let_5 tptp.lUnaryFunction_THFTYPE_i) (@ _let_7 tptp.lAsymmetricRelation_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IiioI tptp.lMeasureFn_THFTYPE_i) tptp.lTotalValuedRelation_THFTYPE_i) (@ (@ _let_8 tptp.n1_THFTYPE_i) tptp.lProcess_THFTYPE_i) (@ _let_2 tptp.lTotalValuedRelation_THFTYPE_i) (@ _let_10 tptp.lBinaryPredicate_THFTYPE_i) (@ (@ _let_9 tptp.n2_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.subProcess_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i) (@ (@ _let_9 tptp.n1_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i) (@ _let_4 tptp.lAsymmetricRelation_THFTYPE_i) (@ _let_6 tptp.lUnaryFunction_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.subrelation_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i) (@ _let_6 tptp.lTotalValuedRelation_THFTYPE_i) (@ (@ _let_8 tptp.n2_THFTYPE_i) tptp.lProcess_THFTYPE_i) (@ (@ (@ tptp.domain_THFTYPE_IiiioI tptp.agent_THFTYPE_i) tptp.n1_THFTYPE_i) tptp.lProcess_THFTYPE_i) (@ (@ (@ tptp.domain_THFTYPE_IIiiIiioI tptp.lEndFn_THFTYPE_IiiI) tptp.n1_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IiioI tptp.equal_THFTYPE_i) tptp.lBinaryPredicate_THFTYPE_i) (@ _let_7 tptp.lBinaryPredicate_THFTYPE_i) (@ _let_3 tptp.lTotalValuedRelation_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.subclass_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i) (@ _let_6 tptp.lTemporalRelation_THFTYPE_i) (@ (@ (@ tptp.domain_THFTYPE_IIiiIiioI tptp.lBeginFn_THFTYPE_IiiI) tptp.n1_THFTYPE_i) tptp.lTimeInterval_THFTYPE_i) (@ _let_2 tptp.lUnaryFunction_THFTYPE_i) (@ _let_5 tptp.lTemporalRelation_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IiioI tptp.attribute_THFTYPE_i) tptp.lAsymmetricRelation_THFTYPE_i) (@ (@ tptp.instance_THFTYPE_IIiioIioI tptp.instance_THFTYPE_IiioI) tptp.lBinaryPredicate_THFTYPE_i) (@ _let_3 tptp.lUnaryFunction_THFTYPE_i) (@ _let_4 tptp.lBinaryPredicate_THFTYPE_i) (@ _let_3 tptp.lTemporalRelation_THFTYPE_i) (@ _let_2 tptp.lTemporalRelation_THFTYPE_i) _let_1 true)))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))
% 0.20/0.60 )
% 0.20/0.60 % SZS output end Proof for CSR130^2
% 0.20/0.60 % cvc5---1.0.5 exiting
% 0.20/0.60 % cvc5---1.0.5 exiting
%------------------------------------------------------------------------------