let s be State of SCM+FSA; :: thesis: for p being the Instructions of SCM+FSA -valued ManySortedSet of NAT
for I being InitClosed Program of SCM+FSA st p +* I halts_on s +* (Initialize ((intloc 0) .--> 1)) holds
for J being Program of SCM+FSA
for k being Element of NAT st k <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) holds
NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),k)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),k))
let p be the Instructions of SCM+FSA -valued ManySortedSet of NAT ; :: thesis: for I being InitClosed Program of SCM+FSA st p +* I halts_on s +* (Initialize ((intloc 0) .--> 1)) holds
for J being Program of SCM+FSA
for k being Element of NAT st k <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) holds
NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),k)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),k))
let I be InitClosed Program of SCM+FSA; :: thesis: ( p +* I halts_on s +* (Initialize ((intloc 0) .--> 1)) implies for J being Program of SCM+FSA
for k being Element of NAT st k <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) holds
NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),k)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),k)) )
assume A1: p +* I halts_on s +* (Initialize ((intloc 0) .--> 1)) ; :: thesis: for J being Program of SCM+FSA
for k being Element of NAT st k <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) holds
NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),k)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),k))
set s1 = s +* (Initialize ((intloc 0) .--> 1));
set p1 = p +* I;
A2: I c= p +* I by FUNCT_4:26;
let J be Program of SCM+FSA; :: thesis: for k being Element of NAT st k <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) holds
NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),k)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),k))
set s2 = s +* (Initialize ((intloc 0) .--> 1));
set p2 = p +* (I ';' J);
defpred S1[ Nat] means ( $1 <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) implies NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),$1)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),$1)) );
A3: for m being Element of NAT st S1[m] holds
S1[m + 1]
proof
dom (I ';' J) = (dom (Directed I)) \/ (dom (Reloc (J,(card I)))) by FUNCT_4:def 1
.= (dom I) \/ (dom (Reloc (J,(card I)))) by FUNCT_4:105 ;
then A4: dom I c= dom (I ';' J) by XBOOLE_1:7;
set sx = s +* (Initialize ((intloc 0) .--> 1));
set px = p +* (I ';' J);
A5: I ';' J c= p +* (I ';' J) by FUNCT_4:26;
let m be Element of NAT ; :: thesis: ( S1[m] implies S1[m + 1] )
assume A6: ( m <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) implies NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m)) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m)) ) ; :: thesis: S1[m + 1]
assume A7: m + 1 <= LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) ; :: thesis: NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),(m + 1))) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),(m + 1)))
then A8: IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m)) = IC (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m)) by A6, COMPOS_1:230, NAT_1:13;
A9: Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),(m + 1)) = Following ((p +* I),(Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) by EXTPRO_1:4
.= Exec ((CurInstr ((p +* I),(Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m)))),(Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) ;
A10: Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),(m + 1)) = Following ((p +* (I ';' J)),(Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m))) by EXTPRO_1:4
.= Exec ((CurInstr ((p +* (I ';' J)),(Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m)))),(Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m))) ;
Initialize ((intloc 0) .--> 1) c= s +* (Initialize ((intloc 0) .--> 1)) by FUNCT_4:26;
then A11: IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m)) in dom I by Def1, A2;
A12: (p +* I) /. (IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) = (p +* I) . (IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) by PBOOLE:158;
A13: CurInstr ((p +* I),(Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) = I . (IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) by A11, A12, A2, GRFUNC_1:8;
A14: (p +* (I ';' J)) /. (IC (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m))) = (p +* (I ';' J)) . (IC (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m))) by PBOOLE:158;
m < LifeSpan ((p +* I),(s +* (Initialize ((intloc 0) .--> 1)))) by A7, NAT_1:13;
then I . (IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) <> halt SCM+FSA by A1, A13, EXTPRO_1:def 14;
then CurInstr ((p +* I),(Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) = (I ';' J) . (IC (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),m))) by A11, A13, SCMFSA6A:54
.= CurInstr ((p +* (I ';' J)),(Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),m))) by A14, A8, A11, A4, A5, GRFUNC_1:8 ;
hence NPP (Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),(m + 1))) = NPP (Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),(m + 1))) by A6, A7, A9, A10, AMISTD_2:def 20, NAT_1:13; :: thesis: verum
end;
( Comput ((p +* I),(s +* (Initialize ((intloc 0) .--> 1))),0) = s +* (Initialize ((intloc 0) .--> 1)) & Comput ((p +* (I ';' J)),(s +* (Initialize ((intloc 0) .--> 1))),0) = s +* (Initialize ((intloc 0) .--> 1)) ) by EXTPRO_1:3;
then A18: S1[ 0 ] ;
thus for k being Element of NAT holds S1[k] from NAT_1:sch 1(A18, A3); :: thesis: verum