let x, y, z be set ; :: thesis: ( x <> [<*y,z*>,nor2] & y <> [<*z,x*>,nor2] & z <> [<*x,y*>,nor2] implies InputVertices (GFA3CarryIStr (x,y,z)) = {x,y,z} )
set f1 = nor2 ;
set f2 = nor2 ;
set f3 = nor2 ;
set xy = [<*x,y*>,nor2];
set yz = [<*y,z*>,nor2];
set zx = [<*z,x*>,nor2];
set Cxy = 1GateCircStr (<*x,y*>,nor2);
set Cyz = 1GateCircStr (<*y,z*>,nor2);
set Czx = 1GateCircStr (<*z,x*>,nor2);
assume that
A1: x <> [<*y,z*>,nor2] and
A2: ( y <> [<*z,x*>,nor2] & z <> [<*x,y*>,nor2] ) ; :: thesis: InputVertices (GFA3CarryIStr (x,y,z)) = {x,y,z}
A3: not [<*x,y*>,nor2] in {y,z} by A1, A2, Lm1;
A4: not [<*z,x*>,nor2] in {x,y,z} by A1, A2, Lm1;
A5: y <> [<*y,z*>,nor2] by FACIRC_2:2;
A6: ( not z in {[<*x,y*>,nor2],[<*y,z*>,nor2]} & not x in {[<*x,y*>,nor2],[<*y,z*>,nor2]} ) by A1, A2, Lm1;
A7: 1GateCircStr (<*x,y*>,nor2) tolerates 1GateCircStr (<*y,z*>,nor2) by CIRCCOMB:47;
InputVertices (GFA3CarryIStr (x,y,z)) = ((InputVertices ((1GateCircStr (<*x,y*>,nor2)) +* (1GateCircStr (<*y,z*>,nor2)))) \ (InnerVertices (1GateCircStr (<*z,x*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ (InnerVertices ((1GateCircStr (<*x,y*>,nor2)) +* (1GateCircStr (<*y,z*>,nor2))))) by CIRCCMB2:5, CIRCCOMB:47
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ (InnerVertices (1GateCircStr (<*y,z*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ (InnerVertices (1GateCircStr (<*x,y*>,nor2))))) \ (InnerVertices (1GateCircStr (<*z,x*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ (InnerVertices ((1GateCircStr (<*x,y*>,nor2)) +* (1GateCircStr (<*y,z*>,nor2))))) by CIRCCMB2:5, CIRCCOMB:47
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ (InnerVertices (1GateCircStr (<*y,z*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ (InnerVertices (1GateCircStr (<*x,y*>,nor2))))) \ (InnerVertices (1GateCircStr (<*z,x*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ((InnerVertices (1GateCircStr (<*x,y*>,nor2))) \/ (InnerVertices (1GateCircStr (<*y,z*>,nor2))))) by A7, CIRCCOMB:11
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ {[<*y,z*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ (InnerVertices (1GateCircStr (<*x,y*>,nor2))))) \ (InnerVertices (1GateCircStr (<*z,x*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ((InnerVertices (1GateCircStr (<*x,y*>,nor2))) \/ (InnerVertices (1GateCircStr (<*y,z*>,nor2))))) by CIRCCOMB:42
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ {[<*y,z*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ {[<*x,y*>,nor2]})) \ (InnerVertices (1GateCircStr (<*z,x*>,nor2)))) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ((InnerVertices (1GateCircStr (<*x,y*>,nor2))) \/ (InnerVertices (1GateCircStr (<*y,z*>,nor2))))) by CIRCCOMB:42
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ {[<*y,z*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ((InnerVertices (1GateCircStr (<*x,y*>,nor2))) \/ (InnerVertices (1GateCircStr (<*y,z*>,nor2))))) by CIRCCOMB:42
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ {[<*y,z*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ({[<*x,y*>,nor2]} \/ (InnerVertices (1GateCircStr (<*y,z*>,nor2))))) by CIRCCOMB:42
.= ((((InputVertices (1GateCircStr (<*x,y*>,nor2))) \ {[<*y,z*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ({[<*x,y*>,nor2]} \/ {[<*y,z*>,nor2]})) by CIRCCOMB:42
.= ((({x,y} \ {[<*y,z*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*y,z*>,nor2))) \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ({[<*x,y*>,nor2]} \/ {[<*y,z*>,nor2]})) by FACIRC_1:40
.= ((({x,y} \ {[<*y,z*>,nor2]}) \/ ({y,z} \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ((InputVertices (1GateCircStr (<*z,x*>,nor2))) \ ({[<*x,y*>,nor2]} \/ {[<*y,z*>,nor2]})) by FACIRC_1:40
.= ((({x,y} \ {[<*y,z*>,nor2]}) \/ ({y,z} \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ({z,x} \ ({[<*x,y*>,nor2]} \/ {[<*y,z*>,nor2]})) by FACIRC_1:40
.= ((({x,y} \ {[<*y,z*>,nor2]}) \/ ({y,z} \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ({z,x} \ {[<*x,y*>,nor2],[<*y,z*>,nor2]}) by ENUMSET1:1
.= (({x,y} \/ ({y,z} \ {[<*x,y*>,nor2]})) \ {[<*z,x*>,nor2]}) \/ ({z,x} \ {[<*x,y*>,nor2],[<*y,z*>,nor2]}) by A1, A5, FACIRC_2:1
.= (({x,y} \/ {y,z}) \ {[<*z,x*>,nor2]}) \/ ({z,x} \ {[<*x,y*>,nor2],[<*y,z*>,nor2]}) by A3, ZFMISC_1:57
.= (({x,y} \/ {y,z}) \ {[<*z,x*>,nor2]}) \/ {z,x} by A6, ZFMISC_1:63
.= ({x,y,y,z} \ {[<*z,x*>,nor2]}) \/ {z,x} by ENUMSET1:5
.= ({y,y,x,z} \ {[<*z,x*>,nor2]}) \/ {z,x} by ENUMSET1:67
.= ({y,x,z} \ {[<*z,x*>,nor2]}) \/ {z,x} by ENUMSET1:31
.= ({x,y,z} \ {[<*z,x*>,nor2]}) \/ {z,x} by ENUMSET1:58
.= {x,y,z} \/ {z,x} by A4, ZFMISC_1:57
.= {x,y,z,z,x} by ENUMSET1:9
.= {x,y,z,z} \/ {x} by ENUMSET1:10
.= {z,z,x,y} \/ {x} by ENUMSET1:73
.= {z,x,y} \/ {x} by ENUMSET1:31
.= {z,x,y,x} by ENUMSET1:6
.= {x,x,y,z} by ENUMSET1:70
.= {x,y,z} by ENUMSET1:31 ;
hence InputVertices (GFA3CarryIStr (x,y,z)) = {x,y,z} ; :: thesis: verum