TSTP Solution File: SEU640^2 by cocATP---0.2.0
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- Process Solution
%------------------------------------------------------------------------------
% File : cocATP---0.2.0
% Problem : SEU640^2 : TPTP v6.1.0. Released v3.7.0.
% Transfm : none
% Format : tptp:raw
% Command : python CASC.py /export/starexec/sandbox/benchmark/theBenchmark.p
% Computer : n183.star.cs.uiowa.edu
% Model : x86_64 x86_64
% CPU : Intel(R) Xeon(R) CPU E5-2609 0 2.40GHz
% Memory : 32286.75MB
% OS : Linux 2.6.32-431.20.3.el6.x86_64
% CPULimit : 300s
% DateTime : Thu Jul 17 13:32:41 EDT 2014
% Result : Theorem 0.41s
% Output : Proof 0.41s
% Verified :
% SZS Type : None (Parsing solution fails)
% Syntax : Number of formulae : 0
% Comments :
%------------------------------------------------------------------------------
%----ERROR: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% % Problem : SEU640^2 : TPTP v6.1.0. Released v3.7.0.
% % Command : python CASC.py /export/starexec/sandbox/benchmark/theBenchmark.p
% % Computer : n183.star.cs.uiowa.edu
% % Model : x86_64 x86_64
% % CPU : Intel(R) Xeon(R) CPU E5-2609 0 @ 2.40GHz
% % Memory : 32286.75MB
% % OS : Linux 2.6.32-431.20.3.el6.x86_64
% % CPULimit : 300
% % DateTime : Thu Jul 17 10:59:51 CDT 2014
% % CPUTime : 0.41
% Python 2.7.5
% Using paths ['/home/cristobal/cocATP/CASC/TPTP/', '/export/starexec/sandbox/benchmark/', '/export/starexec/sandbox/benchmark/']
% FOF formula (<kernel.Constant object at 0x231ea70>, <kernel.DependentProduct object at 0x231eea8>) of role type named in_type
% Using role type
% Declaring in:(fofType->(fofType->Prop))
% FOF formula (<kernel.Constant object at 0x231ecf8>, <kernel.Single object at 0x231e4d0>) of role type named emptyset_type
% Using role type
% Declaring emptyset:fofType
% FOF formula (<kernel.Constant object at 0x231eea8>, <kernel.DependentProduct object at 0x231ec20>) of role type named setadjoin_type
% Using role type
% Declaring setadjoin:(fofType->(fofType->fofType))
% FOF formula (<kernel.Constant object at 0x231eb90>, <kernel.DependentProduct object at 0x231e3f8>) of role type named dsetconstr_type
% Using role type
% Declaring dsetconstr:(fofType->((fofType->Prop)->fofType))
% FOF formula (<kernel.Constant object at 0x231e680>, <kernel.DependentProduct object at 0x231e7a0>) of role type named singleton_type
% Using role type
% Declaring singleton:(fofType->Prop)
% FOF formula (((eq (fofType->Prop)) singleton) (fun (A:fofType)=> ((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (((eq fofType) A) ((setadjoin Xx) emptyset))))))) of role definition named singleton
% A new definition: (((eq (fofType->Prop)) singleton) (fun (A:fofType)=> ((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (((eq fofType) A) ((setadjoin Xx) emptyset)))))))
% Defined: singleton:=(fun (A:fofType)=> ((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (((eq fofType) A) ((setadjoin Xx) emptyset))))))
% FOF formula (<kernel.Constant object at 0x2207c68>, <kernel.Sort object at 0x25cc878>) of role type named singletonprop_type
% Using role type
% Declaring singletonprop:Prop
% FOF formula (((eq Prop) singletonprop) (forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->(singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx)))))))) of role definition named singletonprop
% A new definition: (((eq Prop) singletonprop) (forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->(singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx))))))))
% Defined: singletonprop:=(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->(singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx)))))))
% FOF formula (<kernel.Constant object at 0x2207cf8>, <kernel.DependentProduct object at 0x231e878>) of role type named ex1_type
% Using role type
% Declaring ex1:(fofType->((fofType->Prop)->Prop))
% FOF formula (((eq (fofType->((fofType->Prop)->Prop))) ex1) (fun (A:fofType) (Xphi:(fofType->Prop))=> (singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx)))))) of role definition named ex1
% A new definition: (((eq (fofType->((fofType->Prop)->Prop))) ex1) (fun (A:fofType) (Xphi:(fofType->Prop))=> (singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx))))))
% Defined: ex1:=(fun (A:fofType) (Xphi:(fofType->Prop))=> (singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx)))))
% FOF formula (singletonprop->(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->((ex1 A) (fun (Xx:fofType)=> (Xphi Xx))))))) of role conjecture named ex1I2
% Conjecture to prove = (singletonprop->(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->((ex1 A) (fun (Xx:fofType)=> (Xphi Xx))))))):Prop
% We need to prove ['(singletonprop->(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->((ex1 A) (fun (Xx:fofType)=> (Xphi Xx)))))))']
% Parameter fofType:Type.
% Parameter in:(fofType->(fofType->Prop)).
% Parameter emptyset:fofType.
% Parameter setadjoin:(fofType->(fofType->fofType)).
% Parameter dsetconstr:(fofType->((fofType->Prop)->fofType)).
% Definition singleton:=(fun (A:fofType)=> ((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (((eq fofType) A) ((setadjoin Xx) emptyset)))))):(fofType->Prop).
% Definition singletonprop:=(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->(singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx))))))):Prop.
% Definition ex1:=(fun (A:fofType) (Xphi:(fofType->Prop))=> (singleton ((dsetconstr A) (fun (Xx:fofType)=> (Xphi Xx))))):(fofType->((fofType->Prop)->Prop)).
% Trying to prove (singletonprop->(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->((ex1 A) (fun (Xx:fofType)=> (Xphi Xx)))))))
% Found x:singletonprop
% Found (fun (x:singletonprop)=> x) as proof of (forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->((ex1 A) (fun (Xx:fofType)=> (Xphi Xx))))))
% Found (fun (x:singletonprop)=> x) as proof of (singletonprop->(forall (A:fofType) (Xphi:(fofType->Prop)), ((forall (Xx:fofType), (((in Xx) A)->(forall (Xy:fofType), (((in Xy) A)->((Xphi Xx)->((Xphi Xy)->(((eq fofType) Xx) Xy)))))))->(((ex fofType) (fun (Xx:fofType)=> ((and ((in Xx) A)) (Xphi Xx))))->((ex1 A) (fun (Xx:fofType)=> (Xphi Xx)))))))
% Got proof (fun (x:singletonprop)=> x)
% Time elapsed = 0.073953s
% node=1 cost=3.000000 depth=1
% ::::::::::::::::::::::
% % SZS status Theorem for /export/starexec/sandbox/benchmark/theBenchmark.p
% % SZS output start Proof for /export/starexec/sandbox/benchmark/theBenchmark.p
% (fun (x:singletonprop)=> x)
% % SZS output end Proof for /export/starexec/sandbox/benchmark/theBenchmark.p
% EOF
%------------------------------------------------------------------------------