%------------------------------------------------------------------------------
% File     : cocATP---0.2.0
% Problem  : SEV302^5 : TPTP v6.2.0. Bugfixed v6.2.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : python CASC.py /export/starexec/sandbox/benchmark/theBenchmark.p

% Computer : n133.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 2.6.32-504.8.1.el6.x86_64
% CPULimit : 300s
% DateTime : Tue Apr 21 16:51:42 EDT 2015

% Result   : Theorem 16.28s
% Output   : Proof 16.38s
% Verified : 
% SZS Type : None (Parsing solution fails)
% Syntax   : Number of formulae    : 0

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.00/0.02  % Problem  : SEV302^5 : TPTP v6.2.0. Bugfixed v6.2.0.
% 0.00/0.03  % Command  : python CASC.py /export/starexec/sandbox/benchmark/theBenchmark.p
% 0.01/1.07  % Computer : n133.star.cs.uiowa.edu
% 0.01/1.07  % Model    : x86_64 x86_64
% 0.01/1.07  % CPU      : Intel(R) Xeon(R) CPU E5-2609 0 @ 2.40GHz
% 0.01/1.07  % Memory   : 32286.75MB
% 0.01/1.07  % OS       : Linux 2.6.32-504.8.1.el6.x86_64
% 0.01/1.07  % CPULimit : 300
% 0.01/1.07  % DateTime : Thu Apr 16 12:27:12 CDT 2015
% 0.01/1.08  % CPUTime  : 
% 0.01/1.09  Python 2.7.5
% 0.26/1.43  Using paths ['/home/cristobal/cocATP/CASC/TPTP/', '/export/starexec/sandbox/benchmark/', '/export/starexec/sandbox/benchmark/']
% 0.26/1.43  FOF formula (<kernel.Constant object at 0x1b73f38>, <kernel.DependentProduct object at 0x1b73b90>) of role type named cNAT_type
% 0.26/1.43  Using role type
% 0.26/1.43  Declaring cNAT:(((fofType->Prop)->Prop)->Prop)
% 0.26/1.43  FOF formula (<kernel.Constant object at 0x1b737a0>, <kernel.DependentProduct object at 0x1b733f8>) of role type named cSUCC_type
% 0.26/1.43  Using role type
% 0.26/1.43  Declaring cSUCC:(((fofType->Prop)->Prop)->((fofType->Prop)->Prop))
% 0.26/1.43  FOF formula (<kernel.Constant object at 0x1b73440>, <kernel.DependentProduct object at 0x1b73f38>) of role type named cZERO_type
% 0.26/1.43  Using role type
% 0.26/1.43  Declaring cZERO:((fofType->Prop)->Prop)
% 0.26/1.43  FOF formula (((eq ((fofType->Prop)->Prop)) cZERO) (fun (Xp:(fofType->Prop))=> (((ex fofType) (fun (Xx:fofType)=> (Xp Xx)))->False))) of role definition named cZERO_def
% 0.26/1.43  A new definition: (((eq ((fofType->Prop)->Prop)) cZERO) (fun (Xp:(fofType->Prop))=> (((ex fofType) (fun (Xx:fofType)=> (Xp Xx)))->False)))
% 0.26/1.43  Defined: cZERO:=(fun (Xp:(fofType->Prop))=> (((ex fofType) (fun (Xx:fofType)=> (Xp Xx)))->False))
% 0.26/1.43  FOF formula (((eq (((fofType->Prop)->Prop)->((fofType->Prop)->Prop))) cSUCC) (fun (Xn:((fofType->Prop)->Prop)) (Xp:(fofType->Prop))=> ((ex fofType) (fun (Xx:fofType)=> ((and (Xp Xx)) (Xn (fun (Xt:fofType)=> ((and (not (((eq fofType) Xt) Xx))) (Xp Xt))))))))) of role definition named cSUCC_def
% 0.26/1.43  A new definition: (((eq (((fofType->Prop)->Prop)->((fofType->Prop)->Prop))) cSUCC) (fun (Xn:((fofType->Prop)->Prop)) (Xp:(fofType->Prop))=> ((ex fofType) (fun (Xx:fofType)=> ((and (Xp Xx)) (Xn (fun (Xt:fofType)=> ((and (not (((eq fofType) Xt) Xx))) (Xp Xt)))))))))
% 0.26/1.43  Defined: cSUCC:=(fun (Xn:((fofType->Prop)->Prop)) (Xp:(fofType->Prop))=> ((ex fofType) (fun (Xx:fofType)=> ((and (Xp Xx)) (Xn (fun (Xt:fofType)=> ((and (not (((eq fofType) Xt) Xx))) (Xp Xt))))))))
% 0.26/1.43  FOF formula (((eq (((fofType->Prop)->Prop)->Prop)) cNAT) (fun (Xn:((fofType->Prop)->Prop))=> (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp Xn))))) of role definition named cNAT_def
% 0.26/1.43  A new definition: (((eq (((fofType->Prop)->Prop)->Prop)) cNAT) (fun (Xn:((fofType->Prop)->Prop))=> (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp Xn)))))
% 0.26/1.43  Defined: cNAT:=(fun (Xn:((fofType->Prop)->Prop))=> (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp Xn))))
% 0.26/1.43  FOF formula (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))->(forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm))))) of role conjecture named cX6102_B
% 0.26/1.43  Conjecture to prove = (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))->(forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm))))):Prop
% 0.26/1.43  Parameter fofType_DUMMY:fofType.
% 0.26/1.43  We need to prove ['(forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))->(forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm)))))']
% 0.26/1.43  Parameter fofType:Type.
% 0.26/1.43  Definition cNAT:=(fun (Xn:((fofType->Prop)->Prop))=> (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp Xn)))):(((fofType->Prop)->Prop)->Prop).
% 2.37/3.57  Definition cSUCC:=(fun (Xn:((fofType->Prop)->Prop)) (Xp:(fofType->Prop))=> ((ex fofType) (fun (Xx:fofType)=> ((and (Xp Xx)) (Xn (fun (Xt:fofType)=> ((and (not (((eq fofType) Xt) Xx))) (Xp Xt)))))))):(((fofType->Prop)->Prop)->((fofType->Prop)->Prop)).
% 2.37/3.57  Definition cZERO:=(fun (Xp:(fofType->Prop))=> (((ex fofType) (fun (Xx:fofType)=> (Xp Xx)))->False)):((fofType->Prop)->Prop).
% 2.37/3.57  Trying to prove (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))->(forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm)))))
% 2.37/3.57  Found x4:(Xp Xm)
% 2.37/3.57  Found (fun (x4:(Xp Xm))=> x4) as proof of (Xp Xm)
% 2.37/3.57  Found (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4) as proof of ((Xp Xm)->(Xp Xm))
% 2.37/3.57  Found (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4) as proof of ((cNAT Xm)->((Xp Xm)->(Xp Xm)))
% 2.37/3.57  Found (and_rect10 (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)) as proof of (Xp Xm)
% 2.37/3.57  Found ((and_rect1 (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)) as proof of (Xp Xm)
% 2.37/3.57  Found (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)) as proof of (Xp Xm)
% 2.37/3.57  Found (fun (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))) as proof of (Xp Xm)
% 2.37/3.57  Found (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))) as proof of ((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp Xm))
% 2.37/3.57  Found (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))) as proof of ((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp Xm)))
% 2.37/3.57  Found (and_rect00 (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))) as proof of (Xp Xm)
% 2.37/3.57  Found ((and_rect0 (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))) as proof of (Xp Xm)
% 2.37/3.57  Found (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))) as proof of (Xp Xm)
% 2.37/3.57  Found (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) x00)) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))) as proof of (Xp Xm)
% 2.37/3.57  Found x1:(Xp cZERO)
% 2.37/3.57  Found x1 as proof of (Xp cZERO)
% 2.37/3.57  Found x1:(Xp cZERO)
% 2.37/3.57  Found x1 as proof of (Xp cZERO)
% 2.37/3.57  Found x1:(Xp cZERO)
% 3.46/4.61  Found x1 as proof of (Xp cZERO)
% 3.46/4.61  Found x1:(Xp cZERO)
% 3.46/4.61  Found x1 as proof of (Xp cZERO)
% 3.46/4.61  Found x4:(Xp0 cZERO)
% 3.46/4.61  Found (fun (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4) as proof of (Xp0 cZERO)
% 3.46/4.61  Found (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4) as proof of ((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->(Xp0 cZERO))
% 3.46/4.61  Found (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4) as proof of ((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->(Xp0 cZERO)))
% 3.46/4.61  Found (and_rect10 (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)) as proof of (Xp0 cZERO)
% 3.46/4.61  Found ((and_rect1 (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)) as proof of (Xp0 cZERO)
% 3.46/4.61  Found (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)) as proof of (Xp0 cZERO)
% 3.46/4.61  Found (fun (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4))) as proof of (Xp0 cZERO)
% 3.46/4.61  Found (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4))) as proof of (((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))->(Xp0 cZERO))
% 3.46/4.61  Found (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4))) as proof of (cNAT cZERO)
% 3.46/4.61  Found ((conj10 (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)))) x1) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 3.46/4.61  Found (((conj1 (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)))) x1) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 3.46/4.61  Found ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)))) x1) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 6.06/7.25  Found ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x3:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x4:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x4) x3)) (Xp0 cZERO)) (fun (x4:(Xp0 cZERO)) (x5:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x4)))) x1) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 6.06/7.25  Found x20:=(x2 Xx):((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 6.06/7.25  Found (x2 Xx) as proof of ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 6.06/7.25  Found (x2 Xx) as proof of ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 6.06/7.25  Found (and_rect10 (x2 Xx)) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found ((and_rect1 (Xp (cSUCC Xx))) (x2 Xx)) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x3)) (Xp (cSUCC Xx))) (x2 Xx)) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x3)) (Xp (cSUCC Xx))) (x2 Xx)) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found x2000:=(x200 x5):(Xp (cSUCC Xx))
% 6.06/7.25  Found (x200 x5) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found ((x20 x4) x5) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found (((x2 Xx) x4) x5) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found (((x2 Xx) x4) x5) as proof of (Xp (cSUCC Xx))
% 6.06/7.25  Found x1:(Xp cZERO)
% 6.06/7.25  Found (fun (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1) as proof of (Xp cZERO)
% 6.06/7.25  Found (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1) as proof of ((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp cZERO))
% 6.06/7.25  Found (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1) as proof of ((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->(Xp cZERO)))
% 6.06/7.25  Found (and_rect00 (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)) as proof of (Xp cZERO)
% 6.06/7.25  Found ((and_rect0 (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)) as proof of (Xp cZERO)
% 6.06/7.25  Found (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)) as proof of (Xp cZERO)
% 6.06/7.25  Found (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)) as proof of (Xp cZERO)
% 6.06/7.25  Found x2:(Xp0 cZERO)
% 6.06/7.25  Found (fun (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2) as proof of (Xp0 cZERO)
% 6.06/7.25  Found (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2) as proof of ((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->(Xp0 cZERO))
% 6.06/7.25  Found (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2) as proof of ((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->(Xp0 cZERO)))
% 6.06/7.26  Found (and_rect00 (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)) as proof of (Xp0 cZERO)
% 6.06/7.26  Found ((and_rect0 (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)) as proof of (Xp0 cZERO)
% 6.06/7.26  Found (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)) as proof of (Xp0 cZERO)
% 6.06/7.26  Found (fun (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2))) as proof of (Xp0 cZERO)
% 6.06/7.26  Found (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2))) as proof of (((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))->(Xp0 cZERO))
% 6.06/7.26  Found (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2))) as proof of (cNAT cZERO)
% 6.06/7.26  Found ((conj10 (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1))) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 6.06/7.26  Found (((conj1 (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1))) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 6.06/7.26  Found ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1))) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 13.47/14.66  Found ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1))) as proof of ((and (cNAT cZERO)) (Xp cZERO))
% 13.47/14.66  Found x30:=(x3 Xx):((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 13.47/14.66  Found (x3 Xx) as proof of ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 13.47/14.66  Found (x3 Xx) as proof of ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 13.47/14.66  Found (and_rect10 (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found ((and_rect1 (Xp (cSUCC Xx))) (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found x3000:=(x300 x5):(Xp (cSUCC Xx))
% 13.47/14.66  Found (x300 x5) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found ((x30 x4) x5) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((x3 Xx) x4) x5) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((x3 Xx) x4) x5) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found x5000:=(x500 x3):(Xp (cSUCC Xx))
% 13.47/14.66  Found (x500 x3) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found ((x50 x2) x3) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((x5 Xx) x2) x3) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((x5 Xx) x2) x3) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found x30:=(x3 Xx):((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 13.47/14.66  Found (x3 Xx) as proof of ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 13.47/14.66  Found (x3 Xx) as proof of ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))
% 13.47/14.66  Found (and_rect10 (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found ((and_rect1 (Xp (cSUCC Xx))) (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (fun (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))) as proof of (Xp (cSUCC Xx))
% 13.47/14.66  Found (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))) as proof of ((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->(Xp (cSUCC Xx)))
% 13.47/14.66  Found (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))) as proof of ((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->(Xp (cSUCC Xx))))
% 16.07/17.25  Found (and_rect00 (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))) as proof of (Xp (cSUCC Xx))
% 16.07/17.25  Found ((and_rect0 (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))) as proof of (Xp (cSUCC Xx))
% 16.07/17.25  Found (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))) as proof of (Xp (cSUCC Xx))
% 16.07/17.25  Found (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))) as proof of (Xp (cSUCC Xx))
% 16.07/17.25  Found x200:=(x20 x4):(Xp0 Xx)
% 16.07/17.25  Found (x20 x4) as proof of (Xp0 Xx)
% 16.07/17.25  Found ((x2 Xp0) x4) as proof of (Xp0 Xx)
% 16.07/17.25  Found ((x2 Xp0) x4) as proof of (Xp0 Xx)
% 16.07/17.25  Found (x60 ((x2 Xp0) x4)) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found ((x6 Xx) ((x2 Xp0) x4)) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found (fun (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))) as proof of ((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->(Xp0 (cSUCC Xx)))
% 16.07/17.25  Found (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))) as proof of ((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->(Xp0 (cSUCC Xx))))
% 16.07/17.25  Found (and_rect10 (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found ((and_rect1 (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found (fun (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))) as proof of (Xp0 (cSUCC Xx))
% 16.07/17.25  Found (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))) as proof of (((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))->(Xp0 (cSUCC Xx)))
% 16.07/17.27  Found (fun (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))) as proof of (cNAT (cSUCC Xx))
% 16.07/17.27  Found (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))) as proof of ((Xp Xx)->(cNAT (cSUCC Xx)))
% 16.07/17.27  Found (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))) as proof of ((cNAT Xx)->((Xp Xx)->(cNAT (cSUCC Xx))))
% 16.07/17.27  Found (and_rect00 (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))))) as proof of (cNAT (cSUCC Xx))
% 16.07/17.27  Found ((and_rect0 (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))))) as proof of (cNAT (cSUCC Xx))
% 16.07/17.27  Found (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))))) as proof of (cNAT (cSUCC Xx))
% 16.18/17.30  Found (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4)))))) as proof of (cNAT (cSUCC Xx))
% 16.18/17.30  Found ((conj10 (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp 
% Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))) as proof of ((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))
% 16.18/17.30  Found (((conj1 (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall 
% (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))) as proof of ((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))
% 16.18/17.30  Found ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall 
% (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))) as proof of ((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))
% 16.18/17.32  Found (fun (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) 
% (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))) as proof of ((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))
% 16.18/17.32  Found (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) 
% P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))) as proof of (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))
% 16.18/17.32  Found (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) 
% P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))) as proof of (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))
% 16.18/17.35  Found ((conj00 ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun 
% (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> 
% (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))))) as proof of ((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))
% 16.18/17.35  Found (((conj0 (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun 
% (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC 
% Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))))) as proof of ((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))
% 16.18/17.37  Found ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp 
% (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC 
% Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))))) as proof of ((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))
% 16.18/17.37  Found ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp 
% (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC 
% Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx))))))) as proof of ((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))
% 16.18/17.38  Found (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 
% cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall 
% (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))) as proof of (Xp Xm)
% 16.28/17.42  Found (fun (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 
% cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall 
% (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))))) as proof of (Xp Xm)
% 16.28/17.42  Found (fun (Xm:((fofType->Prop)->Prop)) (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun 
% (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall 
% (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))))) as proof of ((((and ((and 
% (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm))
% 16.28/17.43  Found (fun (x:((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))) (Xm:((fofType->Prop)->Prop)) (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) 
% (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) 
% (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC 
% Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))))) as proof of (forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm)))
% 16.28/17.45  Found (fun (Xp:(((fofType->Prop)->Prop)->Prop)) (x:((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))) (Xm:((fofType->Prop)->Prop)) (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun 
% (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp 
% Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT 
% Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))))) as proof of (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))->(forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm))))
% 16.28/17.47  Found (fun (Xp:(((fofType->Prop)->Prop)->Prop)) (x:((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))) (Xm:((fofType->Prop)->Prop)) (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun 
% (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp 
% Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT 
% Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4))))) as proof of (forall (Xp:(((fofType->Prop)->Prop)->Prop)), (((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))->(forall (Xm:((fofType->Prop)->Prop)), ((((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm)))->(Xp Xm)))))
% 16.28/17.49  Got proof (fun (Xp:(((fofType->Prop)->Prop)->Prop)) (x:((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))) (Xm:((fofType->Prop)->Prop)) (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) 
% (fun (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) 
% (Xp Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT 
% Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))))
% 16.28/17.49  Time elapsed = 16.031961s
% 16.28/17.49  node=1519 cost=1437.000000 depth=35
% 16.28/17.49::::::::::::::::::::::
% 16.28/17.49  % SZS status Theorem for /export/starexec/sandbox/benchmark/theBenchmark.p
% 16.38/17.58  % SZS output start Proof for /export/starexec/sandbox/benchmark/theBenchmark.p
% 16.38/17.58  (fun (Xp:(((fofType->Prop)->Prop)->Prop)) (x:((and (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))) (Xm:((fofType->Prop)->Prop)) (x0:(((and ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))))))->((and (cNAT Xm)) (Xp Xm))))=> (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp Xm)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> (((fun (P:Type) (x3:((cNAT Xm)->((Xp Xm)->P)))=> (((((and_rect (cNAT Xm)) (Xp Xm)) P) x3) (x0 ((((conj ((and (cNAT cZERO)) (Xp cZERO))) (forall (Xx:((fofType->Prop)->Prop)), (((and (cNAT Xx)) (Xp Xx))->((and (cNAT (cSUCC Xx))) (Xp (cSUCC Xx)))))) ((((conj (cNAT cZERO)) (Xp cZERO)) (fun 
% (Xp0:(((fofType->Prop)->Prop)->Prop)) (x1:((and (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))))=> (((fun (P:Type) (x2:((Xp0 cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx))))) P) x2) x1)) (Xp0 cZERO)) (fun (x2:(Xp0 cZERO)) (x3:(forall (Xx:((fofType->Prop)->Prop)), ((Xp0 Xx)->(Xp0 (cSUCC Xx)))))=> x2)))) (((fun (P:Type) (x1:((Xp cZERO)->((forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx)))))) P) x1) x)) (Xp cZERO)) (fun (x1:(Xp cZERO)) (x2:(forall (Xx:((fofType->Prop)->Prop)), ((cNAT Xx)->((Xp Xx)->(Xp (cSUCC Xx))))))=> x1)))) (fun (Xx:((fofType->Prop)->Prop)) (x1:((and (cNAT Xx)) (Xp Xx)))=> ((((conj (cNAT (cSUCC Xx))) (Xp (cSUCC Xx))) (((fun (P:Type) (x2:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT Xx)) (Xp 
% Xx)) P) x2) x1)) (cNAT (cSUCC Xx))) (fun (x2:(cNAT Xx)) (x3:(Xp Xx)) (Xp0:(((fofType->Prop)->Prop)->Prop)) (x4:((and (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))))=> (((fun (P:Type) (x5:((Xp0 cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))->P)))=> (((((and_rect (Xp0 cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0))))) P) x5) x4)) (Xp0 (cSUCC Xx))) (fun (x5:(Xp0 cZERO)) (x6:(forall (Xx0:((fofType->Prop)->Prop)), ((Xp0 Xx0)->(Xp0 (cSUCC Xx0)))))=> ((x6 Xx) ((x2 Xp0) x4))))))) (((fun (P:Type) (x2:((Xp cZERO)->((forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))->P)))=> (((((and_rect (Xp cZERO)) (forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0)))))) P) x2) x)) (Xp (cSUCC Xx))) (fun (x2:(Xp cZERO)) (x3:(forall (Xx0:((fofType->Prop)->Prop)), ((cNAT Xx0)->((Xp Xx0)->(Xp (cSUCC Xx0))))))=> (((fun (P:Type) (x4:((cNAT Xx)->((Xp Xx)->P)))=> (((((and_rect (cNAT 
% Xx)) (Xp Xx)) P) x4) x1)) (Xp (cSUCC Xx))) (x3 Xx)))))))))) (Xp Xm)) (fun (x3:(cNAT Xm)) (x4:(Xp Xm))=> x4)))))
% 16.38/17.58  % SZS output end Proof for /export/starexec/sandbox/benchmark/theBenchmark.p
%------------------------------------------------------------------------------