let n be Element of NAT ; for R being good Ring
for s1, s2 being State of (SCM R) st not R is trivial holds
for p being non NAT -defined autonomic FinPartState of st p c= s1 & p c= s2 holds
( IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n) & CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n) )
let R be good Ring; for s1, s2 being State of (SCM R) st not R is trivial holds
for p being non NAT -defined autonomic FinPartState of st p c= s1 & p c= s2 holds
( IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n) & CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n) )
let s1, s2 be State of (SCM R); ( not R is trivial implies for p being non NAT -defined autonomic FinPartState of st p c= s1 & p c= s2 holds
( IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n) & CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n) ) )
assume A1:
not R is trivial
; for p being non NAT -defined autonomic FinPartState of st p c= s1 & p c= s2 holds
( IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n) & CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n) )
set Cs2i = Comput (ProgramPart s2),s2,n;
set Cs1i = Comput (ProgramPart s1),s1,n;
let p be non NAT -defined autonomic FinPartState of ; ( p c= s1 & p c= s2 implies ( IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n) & CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n) ) )
assume that
A2:
p c= s1
and
A3:
p c= s2
; ( IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n) & CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n) )
ProgramPart p c= p
by RELAT_1:88;
then A4:
dom (ProgramPart p) c= dom p
by GRFUNC_1:8;
thus A5:
IC (Comput (ProgramPart s1),s1,n) = IC (Comput (ProgramPart s2),s2,n)
CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n)proof
assume A6:
IC (Comput (ProgramPart s1),s1,n) <> IC (Comput (ProgramPart s2),s2,n)
;
contradiction
(
((Comput (ProgramPart s1),s1,n) | (dom p)) . (IC (SCM R)) = (Comput (ProgramPart s1),s1,n) . (IC (SCM R)) &
((Comput (ProgramPart s2),s2,n) | (dom p)) . (IC (SCM R)) = (Comput (ProgramPart s2),s2,n) . (IC (SCM R)) )
by A1, Th25, FUNCT_1:72;
hence
contradiction
by A2, A3, A6, AMI_1:def 25;
verum
end;
IC (Comput (ProgramPart s2),s2,n) in dom (ProgramPart p)
by A1, A3, Th27;
then A7:
((Comput (ProgramPart s2),s2,n) | (dom p)) . (IC (Comput (ProgramPart s2),s2,n)) = (Comput (ProgramPart s2),s2,n) . (IC (Comput (ProgramPart s2),s2,n))
by A4, FUNCT_1:72;
Y:
(ProgramPart (Comput (ProgramPart s1),s1,n)) /. (IC (Comput (ProgramPart s1),s1,n)) = (Comput (ProgramPart s1),s1,n) . (IC (Comput (ProgramPart s1),s1,n))
by COMPOS_1:38;
Z:
(ProgramPart (Comput (ProgramPart s2),s2,n)) /. (IC (Comput (ProgramPart s2),s2,n)) = (Comput (ProgramPart s2),s2,n) . (IC (Comput (ProgramPart s2),s2,n))
by COMPOS_1:38;
IC (Comput (ProgramPart s1),s1,n) in dom (ProgramPart p)
by A1, A2, Th27;
then A8:
((Comput (ProgramPart s1),s1,n) | (dom p)) . (IC (Comput (ProgramPart s1),s1,n)) = (Comput (ProgramPart s1),s1,n) . (IC (Comput (ProgramPart s1),s1,n))
by A4, FUNCT_1:72;
assume
not CurInstr (ProgramPart (Comput (ProgramPart s1),s1,n)),(Comput (ProgramPart s1),s1,n) = CurInstr (ProgramPart (Comput (ProgramPart s2),s2,n)),(Comput (ProgramPart s2),s2,n)
; contradiction
hence
contradiction
by A2, A3, A5, A8, A7, Y, Z, AMI_1:def 25; verum