let x, y, c be set ; :: thesis: ( x <> [<*y,c*>,and2 ] & y <> [<*x,c*>,and2a ] & c <> [<*x,y*>,and2a ] & c <> [<*x,y*>,'xor' ] implies for s being State of (BitSubtracterWithBorrowCirc x,y,c)
for a1, a2, a3 being Element of BOOLEAN st a1 = s . x & a2 = s . y & a3 = s . c holds
( (Following s,2) . (BitSubtracterOutput x,y,c) = (a1 'xor' a2) 'xor' a3 & (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3) ) )
assume that
A1: x <> [<*y,c*>,and2 ] and
A2: y <> [<*x,c*>,and2a ] and
A3: c <> [<*x,y*>,and2a ] and
A4: c <> [<*x,y*>,'xor' ] ; :: thesis: for s being State of (BitSubtracterWithBorrowCirc x,y,c)
for a1, a2, a3 being Element of BOOLEAN st a1 = s . x & a2 = s . y & a3 = s . c holds
( (Following s,2) . (BitSubtracterOutput x,y,c) = (a1 'xor' a2) 'xor' a3 & (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3) )
set f = 'xor' ;
set S1 = 2GatesCircStr x,y,c,'xor' ;
set S2 = BorrowStr x,y,c;
set A = BitSubtracterWithBorrowCirc x,y,c;
set A1 = BitSubtracterCirc x,y,c;
set A2 = BorrowCirc x,y,c;
let s be State of (BitSubtracterWithBorrowCirc x,y,c); :: thesis: for a1, a2, a3 being Element of BOOLEAN st a1 = s . x & a2 = s . y & a3 = s . c holds
( (Following s,2) . (BitSubtracterOutput x,y,c) = (a1 'xor' a2) 'xor' a3 & (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3) )
let a1, a2, a3 be Element of BOOLEAN ; :: thesis: ( a1 = s . x & a2 = s . y & a3 = s . c implies ( (Following s,2) . (BitSubtracterOutput x,y,c) = (a1 'xor' a2) 'xor' a3 & (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3) ) )
assume that
A5: a1 = s . x and
A6: a2 = s . y and
A7: a3 = s . c ; :: thesis: ( (Following s,2) . (BitSubtracterOutput x,y,c) = (a1 'xor' a2) 'xor' a3 & (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3) )
A8: x in the carrier of (2GatesCircStr x,y,c,'xor' ) by FACIRC_1:60;
A9: y in the carrier of (2GatesCircStr x,y,c,'xor' ) by FACIRC_1:60;
A10: c in the carrier of (2GatesCircStr x,y,c,'xor' ) by FACIRC_1:60;
A11: x in the carrier of (BorrowStr x,y,c) by FSCIRC_1:6;
A12: y in the carrier of (BorrowStr x,y,c) by FSCIRC_1:6;
A13: c in the carrier of (BorrowStr x,y,c) by FSCIRC_1:6;
reconsider s1 = s | the carrier of (2GatesCircStr x,y,c,'xor' ) as State of (BitSubtracterCirc x,y,c) by FACIRC_1:26;
reconsider s2 = s | the carrier of (BorrowStr x,y,c) as State of (BorrowCirc x,y,c) by FACIRC_1:26;
reconsider t = s as State of ((BitSubtracterCirc x,y,c) +* (BorrowCirc x,y,c)) ;
A14: InputVertices (BorrowStr x,y,c) = {x,y,c} by A1, A2, A3, Th15;
A15: InnerVertices (2GatesCircStr x,y,c,'xor' ) misses InputVertices (2GatesCircStr x,y,c,'xor' ) by XBOOLE_1:79;
A16: InnerVertices (BorrowStr x,y,c) misses InputVertices (BorrowStr x,y,c) by XBOOLE_1:79;
A17: InnerVertices (2GatesCircStr x,y,c,'xor' ) misses InputVertices (BorrowStr x,y,c) by A4, A14, A15, FACIRC_1:57;
A18: InnerVertices (BorrowStr x,y,c) misses InputVertices (2GatesCircStr x,y,c,'xor' ) by A4, A14, A16, FACIRC_1:57;
A19: dom s1 = the carrier of (2GatesCircStr x,y,c,'xor' ) by CIRCUIT1:4;
then A20: a1 = s1 . x by A5, A8, FUNCT_1:70;
A21: a2 = s1 . y by A6, A9, A19, FUNCT_1:70;
A22: a3 = s1 . c by A7, A10, A19, FUNCT_1:70;
(Following t,2) . (2GatesCircOutput x,y,c,'xor' ) = (Following s1,2) . (2GatesCircOutput x,y,c,'xor' ) by A18, FACIRC_1:32;
hence (Following s,2) . (BitSubtracterOutput x,y,c) = (a1 'xor' a2) 'xor' a3 by A4, A20, A21, A22, FACIRC_1:64; :: thesis: (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3)
A23: dom s2 = the carrier of (BorrowStr x,y,c) by CIRCUIT1:4;
then A24: a1 = s2 . x by A5, A11, FUNCT_1:70;
A25: a2 = s2 . y by A6, A12, A23, FUNCT_1:70;
A26: a3 = s2 . c by A7, A13, A23, FUNCT_1:70;
(Following t,2) . (BorrowOutput x,y,c) = (Following s2,2) . (BorrowOutput x,y,c) by A17, FACIRC_1:33;
hence (Following s,2) . (BorrowOutput x,y,c) = ((('not' a1) '&' a2) 'or' (a2 '&' a3)) 'or' (('not' a1) '&' a3) by A1, A2, A3, A24, A25, A26, Lm2; :: thesis: verum