let ap, bp, cp, dp be non pair set ; :: thesis: for cin being set st cin <> [<*dp,(GFA0AdderOutput (ap,bp,cp))*>,and2] & not cin in InnerVertices (BitGFA0Str (ap,bp,cp)) holds
for s being State of (BitFTA0Circ (ap,bp,cp,dp,cin))
for a1, a2, a3, a4, a5 being Element of BOOLEAN st a1 = s . ap & a2 = s . bp & a3 = s . cp & a4 = s . dp & a5 = s . cin holds
( (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 & (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 )
let cin be set ; :: thesis: ( cin <> [<*dp,(GFA0AdderOutput (ap,bp,cp))*>,and2] & not cin in InnerVertices (BitGFA0Str (ap,bp,cp)) implies for s being State of (BitFTA0Circ (ap,bp,cp,dp,cin))
for a1, a2, a3, a4, a5 being Element of BOOLEAN st a1 = s . ap & a2 = s . bp & a3 = s . cp & a4 = s . dp & a5 = s . cin holds
( (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 & (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 ) )
assume A1: ( cin <> [<*dp,(GFA0AdderOutput (ap,bp,cp))*>,and2] & not cin in InnerVertices (BitGFA0Str (ap,bp,cp)) ) ; :: thesis: for s being State of (BitFTA0Circ (ap,bp,cp,dp,cin))
for a1, a2, a3, a4, a5 being Element of BOOLEAN st a1 = s . ap & a2 = s . bp & a3 = s . cp & a4 = s . dp & a5 = s . cin holds
( (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 & (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 )
set A1 = GFA0AdderOutput (ap,bp,cp);
set C1 = BitGFA0Circ (ap,bp,cp);
set S1 = BitGFA0Str (ap,bp,cp);
set S2 = BitGFA0Str ((GFA0AdderOutput (ap,bp,cp)),cin,dp);
set C2 = BitGFA0Circ ((GFA0AdderOutput (ap,bp,cp)),cin,dp);
set S = BitFTA0Str (ap,bp,cp,dp,cin);
let s be State of (BitFTA0Circ (ap,bp,cp,dp,cin)); :: thesis: for a1, a2, a3, a4, a5 being Element of BOOLEAN st a1 = s . ap & a2 = s . bp & a3 = s . cp & a4 = s . dp & a5 = s . cin holds
( (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 & (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 )
let a1, a2, a3, a4, a5 be Element of BOOLEAN ; :: thesis: ( a1 = s . ap & a2 = s . bp & a3 = s . cp & a4 = s . dp & a5 = s . cin implies ( (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 & (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 ) )
assume that
A2: a1 = s . ap and
A3: a2 = s . bp and
A4: a3 = s . cp and
A5: a4 = s . dp and
A6: a5 = s . cin ; :: thesis: ( (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 & (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 )
reconsider s1 = s | the carrier of (BitGFA0Str (ap,bp,cp)) as State of (BitGFA0Circ (ap,bp,cp)) by FACIRC_1:26;
A7: dom s1 = the carrier of (BitGFA0Str (ap,bp,cp)) by CIRCUIT1:3;
A8: dp in InputVertices (BitFTA0Str (ap,bp,cp,dp,cin)) by A1, Th6;
then A9: (Following s) . dp = a4 by A5, CIRCUIT2:def 5;
A10: cp in InputVertices (BitFTA0Str (ap,bp,cp,dp,cin)) by A1, Th6;
then A11: (Following s) . cp = a3 by A4, CIRCUIT2:def 5;
bp in the carrier of (BitGFA0Str (ap,bp,cp)) by GFACIRC1:36;
then A12: a2 = s1 . bp by A3, A7, FUNCT_1:47;
reconsider t = s as State of ((BitGFA0Circ (ap,bp,cp)) +* (BitGFA0Circ ((GFA0AdderOutput (ap,bp,cp)),cin,dp))) ;
( GFA0AdderOutput (ap,bp,cp) in the carrier of (BitGFA0Str (ap,bp,cp)) & InputVertices (BitGFA0Str (ap,bp,cp)) misses InnerVertices (BitGFA0Str ((GFA0AdderOutput (ap,bp,cp)),cin,dp)) ) by Lm2, GFACIRC1:36;
then A13: (Following (t,2)) . (GFA0AdderOutput (ap,bp,cp)) = (Following (s1,2)) . (GFA0AdderOutput (ap,bp,cp)) by FACIRC_1:32;
cp in the carrier of (BitGFA0Str (ap,bp,cp)) by GFACIRC1:36;
then A14: a3 = s1 . cp by A4, A7, FUNCT_1:47;
ap in the carrier of (BitGFA0Str (ap,bp,cp)) by GFACIRC1:36;
then a1 = s1 . ap by A2, A7, FUNCT_1:47;
hence (Following (s,2)) . (GFA0AdderOutput (ap,bp,cp)) = (a1 'xor' a2) 'xor' a3 by A12, A14, A13, GFACIRC1:39; :: thesis: ( (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 )
A15: bp in InputVertices (BitFTA0Str (ap,bp,cp,dp,cin)) by A1, Th6;
then A16: (Following s) . bp = a2 by A3, CIRCUIT2:def 5;
A17: cin in InputVertices (BitFTA0Str (ap,bp,cp,dp,cin)) by A1, Th6;
then A18: (Following s) . cin = a5 by A6, CIRCUIT2:def 5;
A19: ap in InputVertices (BitFTA0Str (ap,bp,cp,dp,cin)) by A1, Th6;
then ( Following (s,2) = Following (Following s) & (Following s) . ap = a1 ) by A2, CIRCUIT2:def 5, FACIRC_1:15;
hence ( (Following (s,2)) . ap = a1 & (Following (s,2)) . bp = a2 & (Following (s,2)) . cp = a3 & (Following (s,2)) . dp = a4 & (Following (s,2)) . cin = a5 ) by A19, A15, A10, A8, A17, A16, A11, A9, A18, CIRCUIT2:def 5; :: thesis: verum