:: Initialization Halting Concepts and Their Basic Properties of SCM+FSA
:: by JingChao Chen and Yatsuka Nakamura
::
:: Received June 17, 1998
:: Copyright (c) 1998-2016 Association of Mizar Users
:: (Stowarzyszenie Uzytkownikow Mizara, Bialystok, Poland).
:: This code can be distributed under the GNU General Public Licence
:: version 3.0 or later, or the Creative Commons Attribution-ShareAlike
:: License version 3.0 or later, subject to the binding interpretation
:: detailed in file COPYING.interpretation.
:: See COPYING.GPL and COPYING.CC-BY-SA for the full text of these
:: licenses, or see http://www.gnu.org/licenses/gpl.html and
:: http://creativecommons.org/licenses/by-sa/3.0/.
environ
vocabularies NUMBERS, SUBSET_1, AMI_1, SCMFSA_2, FSM_1, SCMFSA6A, TARSKI,
CIRCUIT2, RELAT_1, FUNCT_1, CARD_1, FUNCOP_1, FUNCT_4, XBOOLE_0,
SCMFSA6B, NAT_1, XXREAL_0, ARYTM_3, AMI_3, SF_MASTR, GRAPHSP, MSUALG_1,
AMISTD_2, STRUCT_0, VALUED_1, SCMFSA6C, SCMFSA7B, SCMFSA8B, ARYTM_1,
SCMFSA8C, SCM_HALT, PARTFUN1, EXTPRO_1, RELOC, COMPOS_1, AMISTD_1,
SFMASTR2, SCMFSA_9, FRECHET;
notations TARSKI, XBOOLE_0, ENUMSET1, SUBSET_1, CARD_1, ORDINAL1, CARD_3,
NUMBERS, XCMPLX_0, RELAT_1, FINSEQ_1, FUNCT_1, PARTFUN1, FUNCT_4,
FUNCT_7, PBOOLE, FUNCT_2, VALUED_1, NAT_1, NAT_D, STRUCT_0, MEMSTR_0,
COMPOS_0, COMPOS_1, EXTPRO_1, AMISTD_1, AMISTD_2, SCMFSA_2, FUNCOP_1,
SCMFSA6B, SCMFSA6A, SF_MASTR, SCMFSA8B, SFMASTR1, SCMFSA8C, SCMFSA7B,
SCMFSA_3, SCMFSA6C, XXREAL_0, SCMFSA_M, SCMFSA_X, SCMFSA_9, SCMFSA9A;
constructors SFMASTR1, DOMAIN_1, XXREAL_0, REAL_1, SCM_1, SCMFSA_3, SCMFSA6A,
SF_MASTR, SCMFSA6B, SCMFSA6C, SCMFSA8A, SCMFSA8B, SCMFSA8C, AMISTD_1,
AMISTD_2, NAT_D, RELSET_1, VALUED_1, SCMFSA7B, SCMFSA_9, AMISTD_5,
PBOOLE, PRE_POLY, MEMSTR_0, SCMFSA_1, SCMFSA_M, FUNCT_7, SCMFSA_X,
SCMFSA9A, CARD_3;
registrations XBOOLE_0, FUNCT_1, XREAL_0, NAT_1, INT_1, SCMFSA_2, SCMFSA6A,
SF_MASTR, SCMFSA6B, SCMFSA6C, SCMFSA7B, SCMFSA8A, SCMFSA_9, ORDINAL1,
RELAT_1, COMPOS_1, SFMASTR1, EXTPRO_1, SCMFSA_4, FUNCT_4, FUNCT_7,
PRE_POLY, STRUCT_0, FUNCOP_1, MEMSTR_0, AMI_3, COMPOS_0, SCMFSA_M,
SCMFSA8C, SCMFSA8B, CARD_3, RELSET_1, AMISTD_1, SCMFSA9A, SCMFSA10,
SCMFSA_X, COMPOS_2;
requirements REAL, NUMERALS, BOOLE, SUBSET, ARITHM;
definitions EXTPRO_1, SCMFSA7B, SCMFSA9A;
equalities FUNCOP_1, COMPOS_1, EXTPRO_1, SCMFSA_2, SCMFSA8C, SCMFSA6A,
MEMSTR_0, SCMFSA_M, SCMFSA8B, SCMFSA9A;
expansions EXTPRO_1, SCMFSA7B, SCMFSA_M;
theorems SF_MASTR, FUNCT_1, FUNCOP_1, RELAT_1, SCMFSA6A, FUNCT_4, ENUMSET1,
NAT_1, TARSKI, INT_1, GRFUNC_1, SCMFSA_2, SCMFSA6B, SCMFSA7B, SCMFSA8B,
SCMFSA8C, SCMFSA_3, SCMFSA6C, XBOOLE_0, XBOOLE_1, XREAL_1, ORDINAL1,
XXREAL_0, VALUED_1, PBOOLE, PARTFUN1, AFINSQ_1, FINSEQ_4, COMPOS_1,
SFMASTR1, EXTPRO_1, AMISTD_2, AMISTD_5, MEMSTR_0, AMISTD_1, STRUCT_0,
AMI_2, COMPOS_0, SCMFSA_M, SCMFSA_9, SCMFSA9A, SCMFSA_X;
schemes NAT_1;
begin
reserve m,n for Nat,
I for Program of SCM+FSA,
s,s1,s2 for State of SCM+FSA,
a for Int-Location,
f for FinSeq-Location,
p,p1,p2 for Instruction-Sequence of SCM+FSA;
set SA0 = Start-At(0,SCM+FSA);
set iS = Initialize ((intloc 0) .--> 1);
reconsider EP = {} as PartState of SCM+FSA by FUNCT_1:104,RELAT_1:171;
Lm1: IC iS = 0 by MEMSTR_0:def 11;
Lm2: dom iS = dom ((intloc 0) .--> 1) \/ dom Start-At(0,SCM+FSA)
by FUNCT_4:def 1
.= {intloc 0} \/ dom Start-At(0,SCM+FSA) by FUNCOP_1:13
.= {intloc 0} \/ {IC SCM+FSA} by FUNCOP_1:13;
::$CD
definition
let I be Program of SCM+FSA;
attr I is InitHalting means
:Def1:
for s being State of SCM+FSA st Initialize ((intloc 0) .--> 1) c= s
for P being Instruction-Sequence of SCM+FSA
st I c= P
holds P halts_on s;
attr I is keepInt0_1 means
:Def2:
for s being State of SCM+FSA st Initialize ((intloc 0) .--> 1) c= s
for p st I c= p
for k being Nat holds (Comput(p,s,k)).intloc 0 = 1;
end;
::$CT
theorem Th1:
Macro halt SCM+FSA is InitHalting
proof
let s be State of SCM+FSA;
set m = Macro halt SCM+FSA;
set m1 = m;
assume
A1: iS c= s;
let p be Instruction-Sequence of SCM+FSA;
assume
A2: m c= p;
A3: IC SCM+FSA in dom iS by MEMSTR_0:48;
take 0;
IC Comput(p,s,0) in NAT;
hence IC Comput(p,s,0) in dom p by PARTFUN1:def 2;
A4: m. 0 = halt SCM+FSA by COMPOS_1:58;
dom m = { 0, 1} by COMPOS_1:61;
then
A5: 0 in dom m by TARSKI:def 2;
A6: p/.IC s = p.IC s by PBOOLE:143;
CurInstr(p,Comput(p,s,0))
= CurInstr(p,s)
.= p.0 by Lm1,A1,A6,A3,GRFUNC_1:2
.= halt SCM+FSA by A4,A2,A5,GRFUNC_1:2;
hence thesis;
end;
registration
cluster InitHalting for Program of SCM+FSA;
existence by Th1;
end;
registration
cluster parahalting -> InitHalting for Program of SCM+FSA;
coherence
proof
let I be Program of SCM+FSA;
assume
A1: I is parahalting;
let s be State of SCM+FSA such that
A2: iS c= s;
let P be Instruction-Sequence of SCM+FSA
such that
A3: I c= P;
SA0 c= iS by FUNCT_4:25;
then SA0 c= s by A2,XBOOLE_1:1;
then s is 0-started by MEMSTR_0:29;
hence P halts_on s by A1,A3,AMISTD_1:def 11;
end;
end;
registration
cluster keeping_0 -> keepInt0_1 for Program of SCM+FSA;
coherence
proof
let I be Program of SCM+FSA;
assume
A1: I is keeping_0;
let s be State of SCM+FSA;
assume
A2: iS c= s;
let p;
assume
A3: I c= p;
let k be Nat;
SA0 c= iS by FUNCT_4:25;
then
SA0 c= s by A2,XBOOLE_1:1;
then
A4: s is 0-started by MEMSTR_0:29;
s.intloc 0=1 by A2,SCMFSA_M:30;
hence (Comput(p,s,k)).intloc 0 = 1 by A1,A3,A4,SCMFSA6B:def 4;
end;
end;
::$CT
theorem
for I being InitHalting really-closed Program of SCM+FSA,
a being read-write
Int-Location holds not a in UsedILoc I implies (IExec(I,p,s)).a = s.a
proof
let I be InitHalting really-closed Program of SCM+FSA,
a be read-write Int-Location;
a <> intloc 0 & a <> IC SCM+FSA by SCMFSA_2:56;
then
A1: not a in dom iS by SCMFSA_M:11,TARSKI:def 2;
A2: (IExec(I,p,s)).a = (Result(p+*I,Initialized s)).a by SCMFSA6B:def 1;
A3: iS c= Initialized s by FUNCT_4:25;
A4: I c= p+*I by FUNCT_4:25;
then p+*I halts_on Initialized s by Def1,A3;
then consider n such that
A5: Result(p+*I,Initialized s) = Comput(p +* I,s+* iS,n)
and
CurInstr(p+*I,Result(p+*I,Initialized s))
= halt SCM+FSA by EXTPRO_1:def 9;
IC Initialized s = 0 by MEMSTR_0:def 11;
then IC Initialized s in dom I by AFINSQ_1:65;
then
A6: for m st m < n holds IC
Comput(p+*I,Initialized s,m) in dom I by A4,AMISTD_1:21;
assume not a in UsedILoc I;
hence (IExec(I,p,s)).a
= (Initialized s).a by A2,A5,A6,FUNCT_4:25,SF_MASTR:61
.= s.a by A1,FUNCT_4:11;
end;
theorem
for I being InitHalting really-closed Program of SCM+FSA,
f being FinSeq-Location
holds not f in UsedI*Loc I implies (IExec(I,p,s)).f = s.f
proof
let I be InitHalting really-closed Program of SCM+FSA,
f be FinSeq-Location;
f <> intloc 0 & f <> IC SCM+FSA by SCMFSA_2:57,58;
then
A1: not f in dom iS by SCMFSA_M:11,TARSKI:def 2;
A2: (IExec(I,p,s)).f = (Result(p+*I,Initialized s)).f
by SCMFSA6B:def 1;
A3: iS c= Initialized s by FUNCT_4:25;
A4: I c= p+*I by FUNCT_4:25;
then p+*I halts_on Initialized s by Def1,A3;
then consider n such that
A5: Result(p+*I,Initialized s) = Comput(p +* I,Initialized s,n) and
CurInstr(p+*I,Result(p+*I,Initialized s))
= halt SCM+FSA by EXTPRO_1:def 9;
IC Initialized s = 0 by MEMSTR_0:def 11;
then IC Initialized s in dom I by AFINSQ_1:65;
then
A6: for m st m < n holds IC
Comput(p+*I,Initialized s,m) in dom I by AMISTD_1:21,A4;
assume not f in UsedI*Loc I;
hence (IExec(I,p,s)).f = (Initialized s).f by A2,A5,A6,FUNCT_4:25,SF_MASTR:63
.= s.f by A1,FUNCT_4:11;
end;
registration
cluster InitHalting -> non empty for Program of SCM+FSA;
coherence;
end;
theorem Th4:
for J being InitHalting really-closed Program of SCM+FSA
st Initialize ((intloc 0) .--> 1) c= s1 & J c= p1
for n being Nat st
Reloc(J,n) c= p2 &
IC s2 = n & DataPart s1 = DataPart s2
for i being Nat holds
IC Comput(p1,s1,i) + n = IC Comput(p2,s2,i) &
IncAddr(CurInstr(p1,Comput(p1,s1,i)),n) = CurInstr(p2,Comput(p2,s2,i)) &
DataPart Comput(p1,s1,i) = DataPart Comput(p2,s2,i)
proof
let J be InitHalting really-closed Program of SCM+FSA;
assume that
A1: iS c= s1 and
A2: J c= p1;
let n be Nat;
assume that
A3: Reloc(J,n) c= p2 and
A4: IC s2 = n and
A5: DataPart s1 = DataPart s2;
A6: DataPart Comput(p1,s1,0) = DataPart s2 by A5
.= DataPart Comput(p2,s2,0);
defpred P[Nat] means IC Comput(p1,s1,$1) + n = IC Comput(p2,s2,$1) &
IncAddr(CurInstr(p1,Comput(p1,s1,$1)),n)
= CurInstr(p2,Comput(p2,s2,$1)) &
DataPart Comput(p1,s1,$1) = DataPart Comput(p2,s2,$1);
A7: for k being Nat st P[k] holds P[k + 1]
proof
let k be Nat;
A8: Comput(p1,s1,k+1) = Following(p1,Comput(p1,s1,k)) by EXTPRO_1:3
.= Exec(CurInstr(p1,Comput(p1,s1,k)),
Comput(p1,s1,k));
reconsider l = IC Comput(p1,s1,k+1) as Element of NAT;
reconsider j = CurInstr(p1,
Comput(p1,s1,k+1)) as Instruction of SCM+FSA;
A9: Comput(p2,s2,k+1) = Following(p2,
Comput(p2,s2,k)) by EXTPRO_1:3
.= Exec(CurInstr(p2,Comput(p2,s2,k)),
Comput(p2,s2,k));
IC s1 = 0 by A1,MEMSTR_0:47;
then IC s1 in dom J by AFINSQ_1:65;
then
A10: IC Comput(p1,s1,k+1) in dom J by A2,AMISTD_1:21;
assume
A11: P[k];
hence
IC Comput(p1,s1,k+1) + n = IC Comput(p2,s2,k+1)
by A8,A9,SCMFSA6A:8;
then
A12: IC Comput(p2,s2,k+1) in dom Reloc(J,n) by A10,COMPOS_1:46;
A13: l in dom J by A10;
j = p1.IC Comput(p1,s1,k+1) by PBOOLE:143
.= J.l by A10,A2,GRFUNC_1:2;
hence IncAddr(CurInstr(p1,Comput(p1,s1,k+1)),n)
= Reloc(J,n).(l + n) by A13,COMPOS_1:35
.= (Reloc(J,n)).(IC Comput(p2,s2,k+1))
by A11,A8,A9,SCMFSA6A:8
.= p2.IC Comput(p2,s2,k+1) by A12,A3,GRFUNC_1:2
.= CurInstr(p2,Comput(p2,s2,k+1)) by PBOOLE:143;
thus thesis by A11,A8,A9,SCMFSA6A:8;
end;
A14: 0 in dom J by AFINSQ_1:65;
A15: 0 in dom J by AFINSQ_1:65;
A16: IC SCM+FSA in dom iS by MEMSTR_0:48;
then
A17: p1.IC s1 = p1.IC iS by A1,GRFUNC_1:2
.= J. 0 by A15,A2,Lm1,GRFUNC_1:2;
let i be Nat;
0 in dom J by AFINSQ_1:65;
then
A18: (0 + n) in dom Reloc(J,n) by COMPOS_1:46;
A19: IC Comput(p1,s1,0) = s1.IC SCM+FSA
.= 0 by Lm1,A1,A16,GRFUNC_1:2;
A20: p2/.IC s2 = p2.IC s2 by PBOOLE:143;
A21: p1/.IC s1 = p1.IC s1 by PBOOLE:143;
IncAddr(CurInstr(p1,Comput(p1,s1,0)),n)
= IncAddr(CurInstr(p1,s1),n)
.= Reloc(J,n).( 0 + n) by A17,A14,A21,COMPOS_1:35
.= CurInstr(p2,s2) by A4,A18,A20,A3,GRFUNC_1:2
.= CurInstr(p2,Comput(p2,s2,0));
then
A22: P[0] by A4,A19,A6;
for k being Nat holds P[k] from NAT_1:sch 2(A22,A7);
hence thesis;
end;
theorem Th5:
for I being InitHalting really-closed Program of SCM+FSA st
Initialize ((intloc 0) .--> 1) c= s1 &
Initialize ((intloc 0) .--> 1) c= s2 &
I c= p1 & I c= p2 &
s1 = s2
for k being Nat holds
Comput(p1,s1,k) = Comput(p2,s2,k) &
CurInstr(p1,Comput(p1,s1,k)) = CurInstr(p2,Comput(p2,s2,k))
proof
let I be InitHalting really-closed Program of SCM+FSA;
assume that
A1: iS c= s1 and
A2: iS c= s2 and
A3: I c= p1 and
A4: I c= p2 and
A5: s1 = s2;
let k be Nat;
IC s1 = 0 by A1,MEMSTR_0:47;
then IC s1 in dom I by AFINSQ_1:65;
then
A6: IC Comput(p1,s1,k) in dom I by AMISTD_1:21,A3;
IC s2 = 0 by A2,MEMSTR_0:47;
then
A7: IC s2 in dom I by AFINSQ_1:65;
then
A8: IC Comput(p2,s2,k) in dom I by AMISTD_1:21,A4;
for m being Nat st m < k holds IC(Comput(p2,s2,m)) in dom I
by AMISTD_1:21,A4,A7;
hence
A9: Comput(p1,s1,k) = Comput(p2,s2,k)
by A5,A3,A4,AMISTD_2:10;
thus CurInstr(p2,Comput(p2,s2,k))
= p2.IC Comput(p2,s2,k) by PBOOLE:143
.= I.IC Comput(p2,s2,k) by A8,A4,GRFUNC_1:2
.= p1.IC Comput(p1,s1,k) by A9,A6,A3,GRFUNC_1:2
.= CurInstr(p1,Comput(p1,s1,k)) by PBOOLE:143;
end;
theorem Th6:
for I being InitHalting really-closed Program of SCM+FSA
st Initialize ((intloc 0) .--> 1) c= s1 &
Initialize ((intloc 0) .--> 1) c= s2 & I c= p1 & I c= p2 &
s1 = s2
holds LifeSpan(p1,s1) = LifeSpan(p2,
s2) & Result(p1,s1) = Result(p2,s2)
proof
let I be InitHalting really-closed Program of SCM+FSA;
assume that
A1: iS c= s1 and
A2: iS c= s2 and
A3: I c= p1 and
A4: I c= p2 and
A5: s1 = s2;
A6: p2 halts_on s2 by A2,Def1,A4;
A7: p1 halts_on s1 by A1,Def1,A3;
A8: now
let l be Nat;
assume
A9: CurInstr(p2,Comput(p2,s2,l)) = halt SCM+FSA;
CurInstr(p1,Comput(p1,s1,l)) = CurInstr(p2,Comput(p2,s2,l))
by A1,A5,Th5,A3,A4;
hence LifeSpan(p1,s1) <= l by A7,A9,EXTPRO_1:def 15;
end;
CurInstr(p2,Comput(p2,s2,LifeSpan(p1,s1)))
= CurInstr(p1,Comput(p1,s1,LifeSpan(p1,s1))) by A1,A5,Th5,A3,A4
.= halt SCM+FSA by A7,EXTPRO_1:def 15;
hence
A10: LifeSpan(p1,s1) = LifeSpan(p2,s2) by A8,A6,EXTPRO_1:def 15;
p2 halts_on s2 by A2,Def1,A4;
then
A11: Result(p2,s2) = Comput(p2,s2,LifeSpan(p1,s1))
by A10,EXTPRO_1:23;
p1 halts_on s1 by A1,Def1,A3;
then
Result(p1,s1) = Comput(p1,s1,LifeSpan(p1,s1)) by EXTPRO_1:23;
hence thesis by A1,A5,A11,Th5,A3,A4;
end;
registration
cluster keeping_0 InitHalting for Program of SCM+FSA;
existence
proof
take Stop SCM+FSA;
thus thesis;
end;
end;
registration
cluster keepInt0_1 InitHalting for really-closed Program of SCM+FSA;
existence
proof
take Stop SCM+FSA;
thus thesis;
end;
end;
theorem Th7:
for I being keepInt0_1 InitHalting Program of SCM+FSA holds
IExec(I,p,s).intloc 0 = 1
proof
let I be keepInt0_1 InitHalting Program of SCM+FSA;
A1: iS c= Initialized s by FUNCT_4:25;
A2: I c= p+*I by FUNCT_4:25;
then p+*I halts_on Initialized s by Def1,A1;
then
A3: iS c= Initialized s &
ex n st Result(p +* I,Initialized s) =
Comput(p +* I,Initialized s,n) &
CurInstr(p+*I,Result(p+*I,Initialized s))
= halt SCM+FSA by EXTPRO_1:def 9,FUNCT_4:25;
thus IExec(I,p,s).intloc 0 = (Result(p+*I,Initialized s)).intloc 0
by SCMFSA6B:def 1
.= 1 by A3,A2,Def2;
end;
theorem Th8:
for I being really-closed Program of SCM+FSA, J being Program of
SCM+FSA st Initialize ((intloc 0) .--> 1) c= s & I c= p &
p halts_on s
for m st m <= LifeSpan(p,s) holds
Comput(p,s,m) = Comput(p+*(I ";" J),s,m)
proof
let I be really-closed Program of SCM+FSA, J be Program of SCM+FSA;
assume that
A1: iS c= s and
A2: I c= p and
A3: p halts_on s;
defpred X[Nat] means $1 <= LifeSpan(p,s) implies
Comput(p,s,$1) = Comput(p+*(I ";" J),s,$1);
A4: for m st X[m] holds X[m+1]
proof
set px = p+*(I ";" J);
let m;
A5: I ";" J c= px by FUNCT_4:25;
assume
A6: m <= LifeSpan(p,s) implies
Comput(p,s,m) = Comput(p+*(I ";" J),s,m);
dom(I ";" J) = dom I \/ dom Reloc(J, card I) by SCMFSA6A:39;
then
A7: {} c= Comput(px,s,m) & dom I c= dom(I ";" J) by XBOOLE_1:2,7;
A8: Comput(p,s,m+1) = Following(p,Comput(p,s,m)) by EXTPRO_1:3
.= Exec(CurInstr(p,Comput(p,s,m)),Comput(p,s,m));
A9: Comput(px,s,m+1) = Following(px,Comput(px,s,m)) by EXTPRO_1:3
.= Exec(CurInstr(px,Comput(px,s,m)),
Comput(px,s,m));
IC s = 0 by A1,MEMSTR_0:47;
then IC s in dom I by AFINSQ_1:65;
then
A10: IC Comput(p,s,m) in dom I by AMISTD_1:21,A2;
A11: p/.IC Comput(p,s,m) = p.IC Comput(p,s,m) by PBOOLE:143;
A12: CurInstr(p,Comput(p,s,m))
= I.IC(Comput(p,s,m)) by A10,A11,A2,GRFUNC_1:2;
assume
A13: m+1 <= LifeSpan(p,s);
A14: px/.IC Comput(px,s,m)
= px.IC Comput(px,s,m) by PBOOLE:143;
m < LifeSpan(p,s) by A13,NAT_1:13;
then I.IC(Comput(p,s,m)) <> halt SCM+FSA by A3,A12,EXTPRO_1:def 15;
then CurInstr(p,Comput(p,s,m))
= (I ";" J).IC(Comput(p,s,m)) by A10,A12,SCMFSA6A:15
.= CurInstr(px,Comput(px,s,m)) by A13,A10,A7,A14,A5,A6,GRFUNC_1:2,NAT_1:13;
hence thesis by A6,A13,A8,A9,NAT_1:13;
end;
A15: X[0];
thus for m holds X[m] from NAT_1:sch 2(A15,A4);
end;
theorem Th9:
for I being really-closed Program of SCM+FSA
st p+*I halts_on s &
Directed I c= p &
Initialize ((intloc 0) .--> 1) c= s
holds IC Comput(p, s,LifeSpan(p +* I,s) + 1) = card I
proof
set A = NAT;
let I be really-closed Program of SCM+FSA;
assume that
A1: p+*I halts_on s and
A2: Directed I c= p and
A3: iS c= s;
set sISA0 = s +* iS,
pISA0 = p +* I;
set s1 = sISA0 +* EP,
p1 = pISA0 +* (I ";" I);
A4: sISA0 = s by A3,FUNCT_4:98;
A5: I c= pISA0 by FUNCT_4:25;
reconsider sISA0 as State of SCM+FSA;
set m = LifeSpan(pISA0,sISA0);
set l1 = IC Comput(pISA0, sISA0,m);
A6: I c= pISA0 by FUNCT_4:25;
IC sISA0 = 0 by MEMSTR_0:def 11;
then IC sISA0 in dom I by AFINSQ_1:65;
then
A7: l1 in dom I by AMISTD_1:21,A6;
set s2 = sISA0 +* EP,
p2 = pISA0 +* Directed I;
A8: Directed I c= p2 by FUNCT_4:25;
now
let k be Nat;
defpred X[Nat] means $1 <= k implies
Comput(p1, s1,$1) = Comput(p2, s2,$1);
assume
A9: k <= m;
A10: for n being Nat st X[n] holds X[n+1]
proof
let n be Nat;
assume
A11: n <= k implies
Comput(p1, s1,n) = Comput(p2,s2,n);
A12: Comput(p2, s2,n + 1) = Following(p2,Comput(p2,s2,n)) by EXTPRO_1:3
.= Exec(CurInstr(p2,Comput(p2,s2,n)),
Comput(p2, s2,n));
A13: Comput(p1, s1,n + 1) = Following(p1,Comput(p1,s1,n)) by EXTPRO_1:3
.= Exec(CurInstr(p1,Comput(p1,s1,n)),
Comput(p1, s1,n));
A14: n <= n + 1 by NAT_1:12;
assume
A15: n + 1 <= k;
A16: I c= p +* I by FUNCT_4:25;
IC s1 = 0 by MEMSTR_0:def 11;
then
A17: IC s1 in dom I by AFINSQ_1:65;
n <= k by A15,A14,XXREAL_0:2;
then IC Comput(pISA0, sISA0,n)
= IC Comput(p1, s1,n) by A1,A3,Th8,A5,A4,A9,XXREAL_0:2;
then
A18: IC Comput(p1, s1,n) in dom I by AMISTD_1:21,A16,A17;
then
A19: IC Comput(p2, s2,n) in dom Directed I
by A15,A11,A14,FUNCT_4:99,XXREAL_0:2;
A20: CurInstr(p2,Comput(p2,s2,n))
= p2.IC Comput(p2, s2,n) by PBOOLE:143
.= (Directed I).IC Comput(p2, s2,n) by A19,FUNCT_4:13;
dom I c= dom (I ";" I) &
CurInstr(p1, Comput(p1,s1,n)) = p1.IC
Comput(p1, s1,n) by PBOOLE:143,SCMFSA6A:17;
then Directed I c= I ";" I &
CurInstr(p1,Comput(p1,s1,n)) = (I ";" I).IC
Comput(p1, s1,n) by A18,FUNCT_4:13,SCMFSA6A:16;
hence thesis by A11,A15,A14,A20,A13,A12,A19,GRFUNC_1:2,XXREAL_0:2;
end;
A21: X[0];
for n being Nat holds X[n] from NAT_1:sch 2(A21,A10);
then Comput(p1,s1,k) = Comput(p2,s2,k);
hence Comput(pISA0, sISA0,k) = Comput(p2,s2,k)
by A1,A3,A9,Th8,A5,A4;
end;
then
A22: Comput(pISA0, sISA0,m) = Comput(p2,s2,m);
A23: I.l1 = pISA0.l1 by A7,A5,GRFUNC_1:2
.=CurInstr(pISA0,Comput(pISA0,sISA0,m)) by PBOOLE:143
.= halt SCM+FSA by A1,A4,EXTPRO_1:def 15;
IC Comput(p2,s2,m) in dom Directed I by A7,A22,FUNCT_4:99;
then
A24: p2.l1 = (Directed I).l1 by A22,A8,GRFUNC_1:2
.= goto card I by A7,A23,FUNCT_4:106;
A25: Comput(p2, s2,m + 1)
= Following(p2,Comput(p2,s2,m)) by EXTPRO_1:3
.= Exec(goto card I,Comput(p2,s2,m)) by A22,A24,PBOOLE:143;
set m = LifeSpan(pISA0,sISA0);
dom Directed I = dom I by FUNCT_4:99;
then
A26: p +* I +* Directed I = p +* Directed I by FUNCT_4:74
.= p by A2,FUNCT_4:98;
s2 = sISA0
.= s by A3,FUNCT_4:98;
hence
IC Comput(p, s,LifeSpan(p +* I,s) + 1)
= IC Comput(p2, s2,m + 1) by A26
.= card I by A25,SCMFSA_2:69;
end;
theorem Th10:
for I being really-closed Program of SCM+FSA
st p+*I halts_on s & Directed I c= p &
Initialize ((intloc 0) .--> 1) c= s
holds DataPart Comput(p, s,LifeSpan(p +* I,s))
= DataPart Comput(p,s,LifeSpan(p +* I,s) + 1)
proof
set A = NAT;
let I be really-closed Program of SCM+FSA;
assume that
A1: p+*I halts_on s and
A2: Directed I c= p and
A3: iS c= s;
set sISA0 = s +* iS,
pISA0 = p +* I;
set s2 = sISA0 +* EP,
p2 = pISA0 +* Directed I;
A4: iS c= sISA0 by FUNCT_4:25;
A5: I c= p+*I by FUNCT_4:25;
A6: sISA0 = s by A3,FUNCT_4:98;
reconsider sISA0 as State of SCM+FSA;
set m = LifeSpan(pISA0,sISA0);
set l1 = IC Comput(pISA0, sISA0,m);
IC sISA0 = 0 by MEMSTR_0:def 11;
then IC sISA0 in dom I by AFINSQ_1:65;
then
A7: l1 in dom I by AMISTD_1:21,A5;
set s2 = sISA0 +* EP,
p2 = pISA0 +* Directed I;
now
set s1 = sISA0 +* EP,
p1 = pISA0 +* (I ";" I);
let k be Nat;
defpred X[Nat] means $1 <= k implies
Comput(p1, s1,$1) = Comput(p2, s2,$1);
assume
A8: k <= m;
A9: for n being Nat st X[n] holds X[n+1]
proof
A10: Directed I c= I ";" I by SCMFSA6A:16;
let n be Nat;
A11: dom I c= dom (I ";" I) by SCMFSA6A:17;
assume
A12: n <= k implies
Comput(p1, s1,n) = Comput(p2,s2,n);
A13: Comput(p2, s2,n + 1) = Following(p2,
Comput(p2,s2,n)) by EXTPRO_1:3
.= Exec(CurInstr(p2,Comput(p2,s2,n)),
Comput(p2, s2,n));
A14: Comput(p1, s1,n + 1) = Following(p1,
Comput(p1,s1,n)) by EXTPRO_1:3
.= Exec(CurInstr(p1,Comput(p1,s1,n)),
Comput(p1, s1,n));
A15: n <= n + 1 by NAT_1:12;
assume
A16: n + 1 <= k;
IC s1 = 0 by MEMSTR_0:def 11;
then
A17: IC s1 in dom I by AFINSQ_1:65;
n <= k by A16,A15,XXREAL_0:2;
then Comput(pISA0, sISA0,n) = Comput(p1, s1,n)
by A1,A4,Th8,A5,A6,A8,XXREAL_0:2;
then
A18: IC Comput(p1, s1,n) in dom I by AMISTD_1:21,A5,A17;
then
A19: IC Comput(p2, s2,n) in dom Directed I
by A16,A12,A15,FUNCT_4:99,XXREAL_0:2;
A20: CurInstr(p2,Comput(p2,s2,n))
= p2.IC Comput(p2, s2,n) by PBOOLE:143
.= (Directed I).IC Comput(p2, s2,n) by A19,FUNCT_4:13;
CurInstr(p1,Comput(p1,s1,n))
= p1.IC Comput(p1, s1,n) by PBOOLE:143
.= (I ";" I).IC Comput(p1, s1,n) by A11,A18,FUNCT_4:13
.= (Directed I).IC Comput(p1, s1,n)
by A10,A16,A19,A12,A15,GRFUNC_1:2,XXREAL_0:2;
hence thesis by A12,A16,A15,A20,A14,A13,XXREAL_0:2;
end;
A21: X[0];
for n being Nat holds X[n] from NAT_1:sch 2(A21,A9);
then Comput(p1,s1,k) = Comput(p2,s2,k);
hence Comput(pISA0, sISA0,k) = Comput(p2,s2,k) by A1,A4,A6,A8,Th8,A5;
end;
then
A22: Comput(pISA0, sISA0,m) = Comput(p2,s2,m);
A23: I.l1 = pISA0.l1 by A7,A5,GRFUNC_1:2
.=CurInstr(pISA0,Comput(pISA0,sISA0,m)) by PBOOLE:143
.= halt SCM+FSA by A1,A6,EXTPRO_1:def 15;
IC Comput(p2,s2,m) in dom Directed I by A7,A22,FUNCT_4:99;
then
A24: p2.l1 = (Directed I).l1 by A22,FUNCT_4:13
.= goto card I by A7,A23,FUNCT_4:106;
Comput(p2, s2,m + 1)
= Following(p2,Comput(p2,s2,m)) by EXTPRO_1:3
.= Exec(goto card I,Comput(p2,s2,m))
by A22,A24,PBOOLE:143;
then
A25: ( for a being Int-Location holds Comput(p2, s2,m + 1).a =
Comput(p2, s2,m). a)& for f being FinSeq-Location holds Comput(
p2, s2,m + 1).f =
Comput(p2, s2,m).f by SCMFSA_2:69;
dom Directed I = dom I by FUNCT_4:99;
then
p +* I +* Directed I = p +* Directed I by FUNCT_4:74
.= p by A2,FUNCT_4:98;
hence thesis by A6,A25,SCMFSA_M:2;
end;
theorem Th11:
for I being InitHalting really-closed Program of SCM+FSA st
Initialize ((intloc 0) .--> 1) c= s & I c= p
for k being Nat st k <= LifeSpan(p,s)
holds CurInstr(p +* Directed I,
Comput(p +* Directed I, s,k)) <> halt SCM+FSA
proof
set A = NAT;
let I be InitHalting really-closed Program of SCM+FSA;
set s2 = s +* EP,
p2 = p +* Directed I;
set m = LifeSpan(p,s);
assume
A1: iS c= s;
assume
A2: I c= p;
then
A3: p halts_on s by A1,Def1;
A4: now
set s1 = s +* EP,
p1 = p +* (I ";" I);
let k be Nat;
defpred X[Nat] means $1 <= k implies
Comput(p1, s1,$1) = Comput(p2, s2,$1);
assume
A5: k <= m;
A6: for n being Nat st X[n] holds X[n+1]
proof
A7: Directed I c= I ";" I by SCMFSA6A:16;
let n be Nat;
A8: dom I c= dom (I ";" I) by SCMFSA6A:17;
assume
A9: n <= k implies
Comput(p1, s1,n) = Comput(p2,s2,n);
A10: Comput(p2, s2,n + 1) = Following(p2,Comput(p2,s2,n))
by EXTPRO_1:3
.= Exec(CurInstr(p2,Comput(p2,s2,n)),Comput(p2, s2,n));
A11: Comput(p1, s1,n + 1) = Following(p1,Comput(p1,s1,n)) by EXTPRO_1:3
.= Exec(CurInstr(p1,Comput(p1,s1,n)),Comput(p1, s1,n));
A12: n <= n + 1 by NAT_1:12;
assume
A13: n + 1 <= k;
IC s1 = 0 by A1,MEMSTR_0:47;
then
A14: IC s1 in dom I by AFINSQ_1:65;
n <= k by A13,A12,XXREAL_0:2;
then Comput(p,s,n) = Comput(p1, s1,n) by A1,A3,Th8,A2,A5,XXREAL_0:2;
then
A15: IC Comput(p1, s1,n) in dom I by AMISTD_1:21,A2,A14;
then
A16: IC Comput(p2, s2,n) in dom Directed I
by A13,A9,A12,FUNCT_4:99,XXREAL_0:2;
A17: CurInstr(p2,Comput(p2,s2,n))
= p2.IC Comput(p2, s2,n) by PBOOLE:143
.= (Directed I).IC Comput(p2, s2,n) by A16,FUNCT_4:13;
CurInstr(p1,Comput(p1,s1,n))
= p1.IC Comput(p1, s1,n) by PBOOLE:143
.= (I ";" I).IC Comput(p1, s1,n) by A8,A15,FUNCT_4:13
.= (Directed I).IC Comput(p1, s1,n)
by A7,A13,A16,A9,A12,GRFUNC_1:2,XXREAL_0:2;
hence thesis by A9,A13,A12,A17,A11,A10,XXREAL_0:2;
end;
A18: X[0];
for n being Nat holds X[n] from NAT_1:sch 2(A18,A6);
then Comput(p1,s1,k) = Comput(p2,s2,k);
hence Comput(p,s,k) = Comput(p2,s2,k) by A1,A3,A5,Th8,A2;
end;
let k be Nat;
set lk = IC Comput(p,s,k);
IC s = 0 by A1,MEMSTR_0:47;
then IC s in dom I by AFINSQ_1:65;
then
A19: IC Comput(p,s,k) in dom I &
dom I = dom Directed I by A2,AMISTD_1:21,
FUNCT_4:99;
then
A20: (Directed I).lk in rng Directed I by FUNCT_1:def 3;
assume k <= LifeSpan(p,s);
then lk = IC Comput(p2,s2,k) by A4;
then
A21: CurInstr(p2,Comput(p2,s2,k))
= p2.lk by PBOOLE:143
.= (Directed I).lk by A19,FUNCT_4:13;
assume
CurInstr(p +* Directed I,
Comput(p +* Directed I, s,k)) = halt SCM+FSA;
hence contradiction by A21,A20,SCMFSA6A:1;
end;
theorem Th12:
for I being really-closed Program of SCM+FSA
st p+*I halts_on Initialized s
for J being Program of SCM+FSA, k being Nat
st k <= LifeSpan(p +* I,Initialized s )
holds Comput(p +* I, (Initialized s),k)
= Comput(p +* (I ";" J), (Initialized s),k)
proof
let I be really-closed Program of SCM+FSA;
assume
A1: p+*I halts_on Initialized s;
set s1 = Initialized s,
p1 = p +* I;
A2: I c= p1 by FUNCT_4:25;
let J be Program of SCM+FSA;
set s2 = Initialized s,
p2 = p +* (I ";" J);
defpred X[Nat] means $1 <= LifeSpan(p1,s1)
implies Comput(p1, s1,$1) = Comput(p2,(s2),$1);
A3: for m st X[m] holds X[m+1]
proof
dom(I ";" J) = dom I \/ dom Reloc(J, card I) by SCMFSA6A:39;
then
A4: dom I c= dom(I ";" J) by XBOOLE_1:7;
set sx = s2,
px = p2;
A5: I ";" J c= p2 by FUNCT_4:25;
let m;
assume
A6: m <= LifeSpan(p1,s1) implies
Comput(p1,s1,m) = Comput(p2,(s2),m);
assume
A7: m+1 <= LifeSpan(p1,s1);
A8: Comput(p1,s1,m+1) = Following(p1,Comput(p1,s1,m)) by EXTPRO_1:3
.= Exec(CurInstr(p1,Comput(p1,s1,m)),
Comput(p1,s1,m));
A9: Comput(px,sx,m+1) = Following(px,Comput(px,sx,m)) by EXTPRO_1:3
.= Exec(CurInstr(px,Comput(px,sx,m)),Comput(px,sx,m));
IC s1 = 0 by MEMSTR_0:def 11;
then
A10: IC s1 in dom I by AFINSQ_1:65;
A11: IC Comput(p1,s1,m) in dom I by AMISTD_1:21,A2,A10;
A12: p1/.IC Comput(p1,s1,m) = p1.IC Comput(p1,s1,m) by PBOOLE:143;
A13: CurInstr(p1,Comput(p1,s1,m))
= I.IC(Comput(p1,s1,m)) by A11,A12,A2,GRFUNC_1:2;
A14: px/.IC Comput(px,sx,m) = px.IC Comput(px,sx,m) by PBOOLE:143;
m < LifeSpan(p1,s1) by A7,NAT_1:13;
then I.IC(Comput(p1,s1,m)) <> halt SCM+FSA by A1,A13,EXTPRO_1:def 15;
then
CurInstr(p1,Comput(p1,s1,m))
= (I ";" J).IC(Comput(p1,s1,m)) by A11,A13,SCMFSA6A:15
.= CurInstr(px,Comput(px,sx,m)) by A14,A7,A11,A4,A5,A6,GRFUNC_1:2,NAT_1:13;
hence thesis by A6,A7,A8,A9,NAT_1:13;
end;
A15: X[0];
thus for k being Nat holds X[k] from NAT_1:sch 2(A15, A3 );
end;
theorem Th13:
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J being InitHalting really-closed Program of SCM+FSA,
s being State of SCM+FSA st
Initialize ((intloc 0) .--> 1) c= s & I ";" J c= p
holds IC Comput(p, s,LifeSpan(p +* I,s) + 1) = card I &
DataPart Comput(p, s,LifeSpan(p +* I,s) + 1) =
DataPart(Comput(p +* I, s,LifeSpan(p +* I,s))
+* Initialize ((intloc 0) .--> 1)) &
Reloc(J,card I) c= p &
Comput(p, s,LifeSpan(p +* I,s) + 1).intloc 0 = 1 & p halts_on s &
LifeSpan(p,s) = LifeSpan(p +* I,s) + 1 +
LifeSpan(p +* I +* J,
Result(p +* I,s) +*Initialize ((intloc 0) .--> 1)) & (J is keeping_0 implies
(Result(p,s)).intloc 0 = 1)
proof
set D = Data-Locations SCM+FSA;
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA;
let J be InitHalting really-closed Program of SCM+FSA;
let s be State of SCM+FSA;
set s1 = s +* EP,
p1 = p +* I;
set s3 = Comput(p1, s,LifeSpan(p1,s)) +* iS,
p3 = p1 +* J;
set m1 = LifeSpan(p1,s);
set m3 = LifeSpan(p3,s3);
A1: J c= p3 by FUNCT_4:25;
assume
A2: iS c= s;
then
A3: s = Initialized s by FUNCT_4:98;
assume
A4: I ";" J c= p;
then
A5: p +*(I ";" J) = p by FUNCT_4:98;
A6: I c= p1 by FUNCT_4:25;
set s4 = Comput(p, s,m1 + 1),
p4 = p;
A7: Directed I c= I ";" J by SCMFSA6A:16;
then
A8: Directed I c= p by A4,XBOOLE_1:1;
A9: p = p +* Directed I by A4,A7,FUNCT_4:98,XBOOLE_1:1;
reconsider m = m1 + 1 + m3 as Element of NAT by ORDINAL1:def 12;
A10: dom Directed I = dom I by FUNCT_4:99;
A11: p1 +* Directed I = p +* (I +* Directed I) by FUNCT_4:14
.= p by A9,A10,FUNCT_4:19;
A12: iS c= s3 by FUNCT_4:25;
then dom iS c= dom s3 by GRFUNC_1:2;
then
A13: dom iS c= the carrier of SCM+FSA by PARTFUN1:def 2;
A14: Reloc(J,card I) c= I ";" J by SCMFSA6A:38;
A15: I c= p+*I by FUNCT_4:25;
then
A16: p+*I halts_on s by Def1,A2;
hence
A17: IC Comput(p, s,LifeSpan(p +* I,s) + 1) = card I by A2,Th9,A8;
A18: now
let x be object;
assume x in dom DataPart iS;
then
A19: x in dom (iS) /\ D by RELAT_1:61;
then
x in dom iS by XBOOLE_0:def 4;
then
A20: x in {IC SCM+FSA,intloc 0} by Lm2,ENUMSET1:1;
A21: x in D by A19,XBOOLE_0:def 4;
per cases by A20,TARSKI:def 2;
suppose
A22: x = intloc 0;
thus (DataPart iS).x
= 1 by A22,A21,FUNCT_1:49,SCMFSA_M:12
.= Comput(p1,s,m1).x by A22,Def2,A6,A2
.= (DataPart Comput(p1,s,m1)).x by A21,FUNCT_1:49;
end;
suppose
x = IC SCM+FSA;
then not x in Data-Locations SCM+FSA by STRUCT_0:3;
hence
(DataPart iS).x = (DataPart Comput(p1,s,m1)).x by A19,XBOOLE_0:def 4;
end;
end;
A23: p3 halts_on s3 by Def1,A1,A12;
dom (DataPart iS) = dom iS /\ D by RELAT_1:61;
then dom (DataPart iS) c= (the carrier of SCM+FSA) /\ D by A13,XBOOLE_1:26;
then dom (DataPart iS) c= dom Comput(p1,s,m1) /\ D by PARTFUN1:def 2;
then
A24: dom (DataPart iS) c= dom DataPart Comput(p1,s,m1) by RELAT_1:61;
A25: DataPart s3 = DataPart Comput(p1,s,m1) +* DataPart iS by FUNCT_4:71;
A26: DataPart iS c= DataPart Comput(p1,s,m1) by A18,A24,GRFUNC_1:2;
A27: DataPart Comput(p1,s,m1) = DataPart s3 by A26,A25,FUNCT_4:98;
A28: p+*I halts_on s by A2,Def1,A15;
DataPart Comput(p,s,m1) = DataPart s3 by A27,A3,A16,Th12,A5;
hence
A29: DataPart Comput(p, s,m1 + 1) = DataPart s3 by A2,Th10,A8,A28;
thus Reloc(J,card I) c= p by A4,A14,XBOOLE_1:1;
A30: Reloc(J,card I) c= p4 by A14,A4,XBOOLE_1:1;
intloc 0 in Int-Locations by AMI_2:def 16;
then
A31: intloc 0 in D by SCMFSA_2:100,XBOOLE_0:def 3;
hence s4.intloc 0 = (DataPart s3).intloc 0 by A29,FUNCT_1:49
.= s3.intloc 0 by A31,FUNCT_1:49
.= 1 by FUNCT_4:13,SCMFSA_M:10,12;
A32: Comput(p,s,m1 + 1 + m3) = Comput(p,Comput(p,s,m1 + 1),m3) by EXTPRO_1:4;
A33: iS c= s3 by FUNCT_4:25;
then IncAddr(CurInstr(p3,Comput(p3,s3,m3)),card I)
= CurInstr(p,Comput(p, s,m1 + 1 + m3))
by A32,A17,A29,Th4,A1,A30;
then
A34: CurInstr(p,Comput(p,s,m))
= IncAddr (halt SCM+FSA,card I) by A23,EXTPRO_1:def 15
.= halt SCM+FSA by COMPOS_0:4;
hence
A35: p halts_on s by EXTPRO_1:29;
A36: now
let k be Nat;
assume m1 + 1 + k < m;
then
A37: k < m3 by XREAL_1:6;
assume
A38: CurInstr(p,Comput(p, s,m1 + 1 + k)) = halt SCM+FSA;
A39: IncAddr(CurInstr(p3,Comput(p3,s3,k)),card I)
= CurInstr(p4,Comput(p,s4,k)) by A17,A29,A33,Th4,A1,A30
.= halt SCM+FSA by A38,EXTPRO_1:4;
InsCode halt SCM+FSA = 0 by COMPOS_1:70;
then InsCode CurInstr(p3,Comput(p3,s3,k)) = 0
by A39,COMPOS_0:def 9;
then CurInstr(p3,Comput(p3,s3,k))
= halt SCM+FSA by SCMFSA_2:95;
hence contradiction by A23,A37,EXTPRO_1:def 15;
end;
now
let k be Nat;
assume
A40: k < m;
per cases;
suppose k <= m1;
hence CurInstr(p,Comput(p,s,k)) <> halt SCM+FSA
by Th11,A11,A2,FUNCT_4:25;
end;
suppose
m1 < k;
then m1 + 1 <= k by NAT_1:13;
then consider kk being Nat such that
A41: m1 + 1 + kk = k by NAT_1:10;
reconsider kk as Element of NAT by ORDINAL1:def 12;
m1+1+kk=k by A41;
hence CurInstr(p,Comput(p,s,k))
<> halt SCM+FSA by A36,A40;
end;
end;
then
A42: for k being Nat st CurInstr(p,Comput(p,s,k))
= halt SCM+FSA
holds m <= k;
then
A43: LifeSpan(p,s) = m by A34,A35,EXTPRO_1:def 15;
I c= p+*I by FUNCT_4:25;
then
A44: p1 halts_on s by Def1,A2;
Comput(p1, s,LifeSpan(p1,s))
= Result(p +* I,s) by A44,EXTPRO_1:23;
hence LifeSpan(p,s) = LifeSpan(p +* I,s) + 1 +
LifeSpan(p +* I +* J,Result(p +* I,s) +* iS)
by A42,A34,A35,EXTPRO_1:def 15;
A45: iS c= s3 by FUNCT_4:25;
A46: DataPart Comput(p3, s3,m3)
= DataPart Comput(p4, s4,m3) by A17,A29,A33,Th4,A1,A30;
assume
A47: J is keeping_0;
thus (Result(p,s)).intloc 0 = Comput(p,s,m).intloc 0 by A35,A43,EXTPRO_1:23
.= Comput(p, s4,m3).intloc 0 by EXTPRO_1:4
.= Comput(p3, s3,m3).intloc 0 by A46,SCMFSA_M:2
.= s3.intloc 0 by A47,A1,SCMFSA6B:def 4
.= 1 by A45,GRFUNC_1:2,SCMFSA_M:10,12;
end;
registration
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J be InitHalting really-closed Program of SCM+FSA;
cluster I ";" J -> InitHalting;
coherence
proof
set D = Data-Locations SCM+FSA;
let s be State of SCM+FSA;
assume
A1: iS c= s;
then
A2: s = Initialized s by FUNCT_4:98;
let p;
assume
A3: I ";" J c= p;
A4: p = p +* (I ";" J) by A3,FUNCT_4:98;
set p1 = p +* I;
set s3 = Comput(p1, s,LifeSpan(p1,s)) +* iS,
p3 = p1 +* J;
A5: J c= p3 by FUNCT_4:25;
set m1 = LifeSpan(p1,s);
set s4 = Comput(p, s,m1 + 1);
A6: I c= p1 by FUNCT_4:25;
A7: Reloc(J,card I) c= I ";" J by SCMFSA6A:38;
set m3 = LifeSpan(p3,s3);
A8: dom DataPart iS = dom iS /\ D by RELAT_1:61;
reconsider m = m1 + 1 + m3 as Element of NAT by ORDINAL1:def 12;
A9: iS c= Initialized s by FUNCT_4:25;
I c= p+*I by FUNCT_4:25;
then
A10: p+*I halts_on Initialized s by Def1,A9;
A11: now
let x be object;
DataPart iS c= iS by RELAT_1:59;
then
A12: dom DataPart iS c= dom iS by RELAT_1:11;
assume
A13: x in dom DataPart iS;
then x in dom iS by A12;
then
A14: x in {intloc 0, IC SCM+FSA } by Lm2,ENUMSET1:1;
per cases by A14,TARSKI:def 2;
suppose
A15: x=intloc 0;
then x in Int-Locations by AMI_2:def 16;
then
A16: x in D by SCMFSA_2:100,XBOOLE_0:def 3;
hence (DataPart Comput(p1,s,m1)).x
= Comput(p1,s,m1).x by FUNCT_1:49
.= 1 by A1,A15,Def2,A6
.=(DataPart iS).x by A16,A15,FUNCT_1:49,SCMFSA_M:12;
end;
suppose
A17: x = IC SCM+FSA;
dom DataPart iS c= Data-Locations SCM+FSA by RELAT_1:58;
hence (DataPart iS).x = (DataPart Comput(p1,s,m1)).x
by A17,A13,STRUCT_0:3;
end;
end;
take m;
IC Comput(p,s,m) in NAT;
hence IC Comput(p,s,m) in dom p by PARTFUN1:def 2;
Directed I c= I ";" J by SCMFSA6A:16;
then
A18: Directed I c= p by A3,XBOOLE_1:1;
iS c= s3 by FUNCT_4:25;
then dom iS c= dom s3 by GRFUNC_1:2;
then dom iS c= the carrier of SCM+FSA by PARTFUN1:def 2;
then dom DataPart iS c= (the carrier of SCM+FSA) /\ D by A8,XBOOLE_1:26;
then dom DataPart iS c= dom Comput(p1,s,m1) /\ D by PARTFUN1:def 2;
then dom DataPart iS c= dom (DataPart Comput(p1,s,m1)) by RELAT_1:61;
then DataPart iS c= DataPart Comput(p1,s,m1) by A11,GRFUNC_1:2;
then
A19: DataPart Comput(p1,s,m1)
= DataPart Comput(p1, s,LifeSpan(p1,s)) +* DataPart iS
by FUNCT_4:98
.= DataPart s3 by FUNCT_4:71;
A20: DataPart Comput(p,s,m1) = DataPart s3 by A19,A2,A4,A10,Th12;
I c= p+*I by FUNCT_4:25;
then
A21: p +* I halts_on s by A1,Def1;
then
A22: DataPart Comput(p, s,m1 + 1) = DataPart s3 by A1,Th10,A20,A18;
A23: Comput(p,s,m1 + 1 + m3) = Comput(p,Comput(p,s,m1 + 1),m3) by EXTPRO_1:4;
A24: Reloc(J,card I) c= p by A7,A3,XBOOLE_1:1;
A25: iS c= s3 by FUNCT_4:25;
A26: IC Comput(p, s,LifeSpan(p +* I,s) + 1) = card I by A21,A18,Th9,A1;
A27: IncAddr(CurInstr(p3,Comput(p3,s3,m3)),card I)
= CurInstr(p,Comput(p,s,m1 + 1 + m3)) by A23,A25,A5,A24,Th4,A26,A22;
p3 halts_on s3 by A5,Def1,A25;
then CurInstr(p,Comput(p,s,m))
= IncAddr (halt SCM+FSA,card I) by A27,EXTPRO_1:def 15
.= halt SCM+FSA by COMPOS_0:4;
hence thesis;
end;
end;
theorem Th14:
for I being keepInt0_1 really-closed Program of SCM+FSA st p+*I halts_on s
for J being really-closed Program of SCM+FSA st
Initialize ((intloc 0) .--> 1) c= s & I ";" J c= p
for k being Element of NAT holds (Comput(p +* I +* J,
(Result(p +* I,s) +* Initialize ((intloc 0) .--> 1)),k) +*
Start-At (IC Comput(p +* I +* J, (
Result(p +* I,s) +* Initialize ((intloc 0) .--> 1)),k) + card I,SCM+FSA))
= Comput(p +* (I ";" J), s,LifeSpan(p +* I,s)+1+k)
proof
let I be keepInt0_1 really-closed Program of SCM+FSA;
assume
A1: p+*I halts_on s;
let J be really-closed Program of SCM+FSA;
set sISA0 = s +* iS,
pISA0 = p +* I;
A2: I c= pISA0 by FUNCT_4:25;
A3: iS c= sISA0 by FUNCT_4:25;
set RI = Result(p +* I,s +* iS),
pRI = p +* I;
set RIJ = RI +* iS,
pRIJ = pRI +* J;
set sIJSA0 = Initialized s,
pIJSA0 = p +* (I ";" J);
defpred X[Nat] means (Comput(pRIJ, RIJ,$1) +* Start-At (IC
Comput(pRIJ, RIJ,$1) + card I,SCM+FSA))
= Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)+1+$1);
assume
A4: iS c= s;
then
A5: s = sIJSA0 by FUNCT_4:98;
assume
A6: I ";" J c= p;
then
A7: pIJSA0 = p by FUNCT_4:98;
A8: for k being Nat st X[k] holds X[k+1]
proof
let k be Nat;
set k1 = k+1;
set CRk = Comput(pRIJ, RIJ,k);
set CRSk = IncIC(CRk,card I);
set CIJk = Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)+1+k);
set CRk1 = Comput(pRIJ, RIJ,k1);
set CRSk1 = CRk1 +* Start-At (IC CRk1 + card I,SCM+FSA);
set CIJk1 = Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)+1+k1);
assume
A9: (Comput(pRIJ, RIJ,k)
+* Start-At (IC Comput(pRIJ,RIJ,k) + card I,SCM+FSA))
= Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)+1+k);
A10: IncAddr(CurInstr(pRIJ,CRk), card I) = CurInstr(pIJSA0,CIJk)
proof
A11: J c= pRIJ by FUNCT_4:25;
A12: Reloc(J, card I) c= I ";" J by SCMFSA6A:38;
I ";" J c= pIJSA0 by FUNCT_4:25;
then
A13: Reloc(J, card I) c= pIJSA0 by A12,XBOOLE_1:1;
A14: pIJSA0/.IC CIJk = pIJSA0.IC CIJk by PBOOLE:143;
A15: CurInstr(pIJSA0,CIJk) = pIJSA0.(IC CRk + card I) by A9,A14,FUNCT_4:113;
reconsider ii = IC CRk as Element of NAT;
IC RIJ = 0 by MEMSTR_0:def 11;
then IC RIJ in dom J by AFINSQ_1:65;
then
A16: IC CRk in dom J by AMISTD_1:21,A11;
then
A17: ii in dom IncAddr(J, card I) by COMPOS_1:def 21;
then
A18: Shift(IncAddr(J, card I), card I).(IC CRk + card I) = IncAddr(J,
card I).ii by VALUED_1:def 12
.= IncAddr(J/.ii, card I) by A16,COMPOS_1:def 21;
dom Shift(IncAddr(J, card I), card I) = { il+card I where il is
Nat: il in dom IncAddr(J, card I)} by VALUED_1:def 12;
then
A19: IC CRk + card I in dom Shift(IncAddr(J, card I), card I) by A17;
A20: J/.ii = J.IC CRk by A16,PARTFUN1:def 6
.= pRIJ.IC CRk by A16,A11,GRFUNC_1:2;
CurInstr(pRIJ,CRk) = pRIJ.IC CRk by PBOOLE:143;
hence
IncAddr(CurInstr(pRIJ,CRk), card I)
= CurInstr(pIJSA0,CIJk) by A15,A18,A19,A20,A13,GRFUNC_1:2;
end;
A21: Exec(CurInstr(pIJSA0,CIJk), CIJk)
= Exec(IncAddr(CurInstr(pRIJ,CRk),card I), CRSk) by A9,A10;
then
A22: Exec(CurInstr(pIJSA0,CIJk), CIJk)
= IncIC(Following(pRIJ,CRk),card I)
by AMISTD_5:4;
CIJk1 = Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,
sISA0)+1+k+1);
then
A23: CIJk1 = Following(pIJSA0,CIJk) by EXTPRO_1:3;
A24: now
let a be Int-Location;
thus CRSk1.a = CRk1.a by SCMFSA_3:3
.= (Following(pRIJ,CRk)).a by EXTPRO_1:3
.= CIJk1.a by A23,A22,SCMFSA_3:3;
end;
A25: now
let f be FinSeq-Location;
thus CRSk1.f = CRk1.f by SCMFSA_3:4
.= (Following(pRIJ,CRk)).f by EXTPRO_1:3
.= IncIC(Following(pRIJ,CRk),card I).f by SCMFSA_3:4
.= CIJk1.f by A23,A21,AMISTD_5:4;
end;
IC CRSk1 = IC CRk1 + card I by FUNCT_4:113
.= IC Following(pRIJ,CRk) + card I by EXTPRO_1:3;
then
IC CRSk1 =
IC IncIC(Following(pRIJ,CRk),card I) by FUNCT_4:113
.= IC CIJk1 by A23,A21,AMISTD_5:4;
hence thesis by A24,A25,SCMFSA_2:61;
end;
A26: sISA0 = s by A4,FUNCT_4:98;
A27: Directed I c= I ";" J by SCMFSA6A:16;
A28: Directed I c= p by A27,A6,XBOOLE_1:1;
A29: now
set s2 = Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)+1+0);
set s1 = IncIC(RIJ,card I);
reconsider RIJ1 = RI +* ((intloc 0 .--> 1)) as State of SCM+FSA;
A30: RIJ = Initialize RIJ1 by FUNCT_4:14;
thus IC s1 = IC RIJ + card I by FUNCT_4:113
.= 0 + card I by A30,FUNCT_4:113
.= IC s2 by A1,A26,Th9,A28,A7,FUNCT_4:25;
A31: DataPart Comput(p,s,LifeSpan(pISA0,sISA0)) =
DataPart Comput(p, s,
LifeSpan(pISA0,sISA0)+1) by A1,A5,Th10,A28,FUNCT_4:25;
hereby
let a be Int-Location;
not a in dom Start-At (IC RIJ + card I,SCM+FSA) by SCMFSA_2:102;
then
A32: s1.a = RIJ.a by FUNCT_4:11;
A33: Comput(pISA0, sISA0,LifeSpan(pISA0,sISA0)).a =
Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)).a by A1,A26,Th12
.= s2.a by A5,A31,A7,SCMFSA_M:2;
per cases;
suppose
A34: a <> intloc 0;
a <> IC SCM+FSA by SCMFSA_2:56;
then not a in dom iS by A34,SCMFSA_M:11,TARSKI:def 2;
hence s1.a = RI.a by A32,FUNCT_4:11
.= s2.a by A1,A26,A33,EXTPRO_1:23;
end;
suppose
A35: a = intloc 0;
then a in dom iS by SCMFSA_M:11,TARSKI:def 2;
hence s1.a
= 1 by A35,A32,FUNCT_4:13,SCMFSA_M:12
.=s2.a by A33,A35,Def2,A2,A3;
end;
end;
let f be FinSeq-Location;
f <> intloc 0 & f <> IC SCM+FSA by SCMFSA_2:57,58;
then
A36: not f in dom iS by SCMFSA_M:11,TARSKI:def 2;
not f in dom Start-At (IC RIJ + card I,SCM+FSA) by SCMFSA_2:103;
hence s1.f = RIJ.f by FUNCT_4:11
.= RI.f by A36,FUNCT_4:11
.= Comput(pISA0, sISA0,LifeSpan(pISA0,sISA0)).f by A1,A26,EXTPRO_1:23
.= Comput(pIJSA0, sIJSA0,LifeSpan(pISA0,sISA0)).f by A1,A26,Th12
.= s2.f by A5,A31,A7,SCMFSA_M:2;
end;
A37: X[0] by A29,SCMFSA_2:61;
for k being Nat holds X[k] from NAT_1:sch 2(A37, A8);
hence thesis by A26;
end;
theorem Th15:
for I being keepInt0_1 really-closed Program of SCM+FSA
st not p+*I halts_on Initialized s
for J being Program of SCM+FSA, k being Nat
holds Comput(p +* I, Initialized s,k)
= Comput(p +* (I ";" J), Initialized s,k)
proof
let I be keepInt0_1 really-closed Program of SCM+FSA;
assume
A1: not p+*I halts_on Initialized s;
set s1 = Initialized s,
p1 = p +* I;
A2: I c= p1 by FUNCT_4:25;
let J be Program of SCM+FSA;
set s2 = Initialized s,
p2 = p +* (I ";" J);
A3: I ";" J c= p2 by FUNCT_4:25;
defpred X[Nat] means Comput(p1, s1,$1) = Comput(p2,s2,$1);
A4: for m st X[m] holds X[m+1]
proof
dom(I ";" J) = dom I \/ dom Reloc(J, card I) by SCMFSA6A:39;
then
A5: dom I c= dom(I ";" J) by XBOOLE_1:7;
set sx = s2,
px = p2;
let m;
A6: Comput(p1,s1,m+1) = Following(p1,
Comput(p1,s1,m)) by EXTPRO_1:3
.= Exec(CurInstr(p1,Comput(p1,s1,m)),
Comput(p1,s1,m));
A7: Comput(px,sx,m+1) = Following(px,
Comput(px,sx,m)) by EXTPRO_1:3
.= Exec(CurInstr(px,Comput(px,sx,m)),
Comput(px,sx,m));
assume
A8: Comput(p1,s1,m) = Comput(p2,(s2),m);
IC s1 = 0 by MEMSTR_0:def 11;
then IC s1 in dom I by AFINSQ_1:65;
then
A9: IC Comput(p1,s1,m) in dom I by AMISTD_1:21,A2;
A10: p1/.IC Comput(p1,s1,m) = p1.IC Comput(p1,s1,m) by PBOOLE:143;
A11: px/.IC Comput(px,sx,m) = px.IC Comput(px,sx,m) by PBOOLE:143;
A12: CurInstr(p1,Comput(p1,s1,m))
= I.IC(Comput(p1,s1,m)) by A9,A10,A2,GRFUNC_1:2;
then I.IC(Comput(p1,s1,m)) <> halt SCM+FSA by A1,EXTPRO_1:29;
then
CurInstr(p1,Comput(p1,s1,m))
= (I ";" J).IC(Comput(p1,s1,m)) by A9,A12,SCMFSA6A:15
.= CurInstr(px,Comput(px,sx,m))
by A8,A9,A5,A11,A3,GRFUNC_1:2;
hence thesis by A8,A6,A7;
end;
A13: X[0];
thus for k being Nat holds X[k] from NAT_1:sch 2(A13, A4 );
end;
theorem Th16:
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J being InitHalting really-closed Program of SCM+FSA holds
LifeSpan(p +* (I ";" J),Initialized s)
= LifeSpan(p+*I,Initialized s) + 1 +
LifeSpan(p +* I +* J,
Result(p+*I,Initialized s)
+*Initialize ((intloc 0) .--> 1))
proof
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA;
let J be InitHalting really-closed Program of SCM+FSA;
set inI=iS;
set inIJ=iS;
set inJ=iS;
A1: inJ c= Result(p+* (I ";" J)+*I,s +* inIJ) +* inJ & inJ c=
Result(p +* I,s +* inI) +* inJ
by FUNCT_4:25;
A2: J c= p +* (I ";" J) +* I +* J & J c= p +* I +* J by FUNCT_4:25;
A3: inI c= s +* inI & inI c= s +* inIJ by FUNCT_4:25;
A4: I c= p +* I & I c= p +* (I ";" J) +* I by FUNCT_4:25;
then
A5: (Result(p+* (I ";" J)+*I,s +* inIJ) +* inJ) = (Result(
p +* I,s +* inI) +* inJ) by Th6,A3;
A6: I ";" J c= p +* (I ";" J) by FUNCT_4:25;
inIJ c= s +* inIJ by FUNCT_4:25;
then
A7: LifeSpan(p +* (I ";" J),s +* inIJ)
= LifeSpan(p+* (I ";" J)+*I,s +* inIJ) + 1 +
LifeSpan(p+* (I ";" J)+*I+*J,
Result(p+* (I ";" J)+*I,s +* inIJ) +* inJ) by Th13,A6;
LifeSpan(p +* I,s +* inI) = LifeSpan(p+* (I ";" J)+*I,
s +* inIJ) by A3,Th6,A4;
hence thesis by A7,A1,A5,Th6,A2;
end;
theorem Th17:
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J being InitHalting really-closed Program of SCM+FSA holds
IExec(I ";" J,p,s) = IncIC(IExec(J,p,IExec(I,p,s)),card I)
proof
set D = (Data-Locations SCM+FSA);
set A = NAT;
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA;
let J be InitHalting really-closed Program of SCM+FSA;
set s1 = Initialized s, p1 = p +* I;
A1: I c= p1 by FUNCT_4:25;
set p2 = p +* (I ";" J);
A2: I ";" J c= p2 by FUNCT_4:25;
set s3 = Initialized Comput(p1, s1,LifeSpan(p1,s1)), p3 = p1 +* J;
A3: iS c= s3 by FUNCT_4:25;
A4: J c= p3 by FUNCT_4:25;
set m1 = LifeSpan(p1,s1);
set m3 = LifeSpan(p3,s3);
A5: iS c= s1 by FUNCT_4:25;
A6: I ";" J c= p2 by FUNCT_4:25;
A7: iS c= Initialized s by FUNCT_4:25;
I c= p+*I by FUNCT_4:25;
then
A8: p1 halts_on s1 by Def1,A7;
A9: iS c= s3 by FUNCT_4:25;
A10: IExec(I,p,s) = Result(p1,s1) & iS c= Result(p1,s1) +* iS
by FUNCT_4:25,SCMFSA6B:def 1;
A11: J c= p +* J by FUNCT_4:25;
A12: iS c= Initialized IExec(I,p,s) &
iS c= s3 by FUNCT_4:25;
A13: J c= p +* J & J c= p3 by FUNCT_4:25;
A14: iS c= s3 by FUNCT_4:25;
A15: iS c= s1 by FUNCT_4:25;
A16: I c= p1 by FUNCT_4:25;
p1 halts_on s1 by A15,Def1,A16;
then
A17: s3 = Initialized Result(p1,s1) by EXTPRO_1:23;
A18: IC Result(p1 +* J,Initialized Result(p1,s1))
= IC Result(p +* J,Initialized IExec(I,p,s)) by A10,Th6,A11,A4;
A19: iS c= s1 by FUNCT_4:25;
A20: I c= p2 +* I by FUNCT_4:25;
A21: LifeSpan(p2 +* I,s1) = m1 by A19,Th6,A16,A20;
Reloc(J,card I) c= I ";" J by SCMFSA6A:38;
then
A22: Reloc(J,card I) c= p2 by A2,XBOOLE_1:1;
A23: iS c= s1 by FUNCT_4:25;
A24: p2 +* I +* (I ";" J) = p2 +* (I +* (I ";" J)) by FUNCT_4:14
.= p2 +* (I ";" J) by SCMFSA6A:18
.= p2
.= p+*(I +* (I ";" J)) by SCMFSA6A:18
.= p1+*(I ";" J) by FUNCT_4:14;
I c= p2+*I by FUNCT_4:25;
then p2 +* I halts_on s1 by Def1,A23;
then DataPart Comput(p2 +* I, s1,m1)
= DataPart Comput(p2 +* I +* (I ";" J), s1,m1) by A19,A21,Th8,A20
.= DataPart Comput(p1,s1,m1) by A15,A8,Th8,A1,A24;
then
A25: DataPart(Comput(p2 +* I, s1,m1) +*iS) =
DataPart
Comput(p1,s1,m1) +* DataPart iS by FUNCT_4:71
.= DataPart(Comput(p1,s1,m1) +*iS) by FUNCT_4:71;
A26: IC Comput(p2,s1,m1+1) = card I &
DataPart Comput(p2,s1,m1+1)
= DataPart(Comput(p2 +* I, s1,m1) +*iS)
by A5,A21,Th13,A6;
then
A27: DataPart Comput(p2, Comput(p2,s1,m1+1),m3)
= DataPart Comput(p3,s3, m3) by A9,A25,Th4,A4,A22;
A28: IC Comput(p2, Comput(p2,s1,m1+1),m3) = IC Comput(p3,s3,m3) + card I
by A26,A9,A25,Th4,A4,A22;
A29: iS c= s1 by FUNCT_4:25;
(I ";" J) c= p+*(I ";" J) by FUNCT_4:25;
then
A30: p2 halts_on s1 by Def1,A29;
A31: IExec(I ";" J,p,s) = Result(p +* (I ";" J),Initialized s)
by SCMFSA6B:def 1
.= Comput(p2,s1,LifeSpan(p2,s1)) by A30,EXTPRO_1:23
.= Comput(p2,s1,m1+1+m3) by A17,Th16;
A32: p1 halts_on s1 by A15,Def1,A1;
IExec(I,p,s) = Result(p+*I,Initialized s) by SCMFSA6B:def 1
.= Comput(p1,s1,m1) by A32,EXTPRO_1:23;
then
A33: Result(p+*J,IExec(I,p,s) +* iS) = Result(p3,s3) by A12,Th6,A13;
A34: p3 halts_on s3 by Def1,A3,A4;
A35: IExec(J,p,IExec(I,p,s)) = Result(p+*J,Initialized IExec(I,p,s))
by SCMFSA6B:def 1
.= Comput(p3,s3,m3) by A33,A34,EXTPRO_1:23;
A36: DataPart IExec(I ";" J,p,s)
= DataPart IExec(J,p,IExec(I,p,s)) by A35,A27,A31,EXTPRO_1:4;
A37: p3 halts_on s3 by A14,Def1,A4;
A38: p2 halts_on s1 by A5,Def1,A2;
p1 halts_on s1 by A15,Def1,A1;
then
A39: s3 = Initialized Result(p1,s1) by EXTPRO_1:23;
A40: IC IExec(I ";" J,p,s)
= IC Result(p+*(I ";" J),Initialized s) by SCMFSA6B:def 1
.= IC Comput(p2,s1,LifeSpan(p2,s1)) by A38,EXTPRO_1:23
.= IC Comput(p2,s1,m1+1+m3) by A17,Th16
.= IC Comput(p3,s3,m3) + card I by A28,EXTPRO_1:4
.= IC Result(p3,s3) + card I by A37,EXTPRO_1:23
.= IC IExec(J,p,IExec(I,p,s)) + card I by A18,A39,SCMFSA6B:def 1;
hereby
reconsider l = IC IExec(J,p,IExec(I,p,s)) + card I as Element of NAT;
A41: dom Start-At(l,SCM+FSA) = {IC SCM+FSA} by FUNCOP_1:13;
A42: now
let x be object;
assume
A43: x in dom IExec(I ";" J,p,s);
per cases by A43,SCMFSA_M:1;
suppose
A44: x is Int-Location;
then x <> IC SCM+FSA by SCMFSA_2:56;
then
A45: not x in dom Start-At(l,SCM+FSA) by A41,TARSKI:def 1;
IExec(I ";" J,p,s).x = IExec(J,p,IExec(I,p,s)).x
by A36,A44,SCMFSA_M:2;
hence
IExec(I ";" J,p,s).x
= IncIC(IExec(J,p,IExec(I,p,s)),card I).x by A45,FUNCT_4:11;
end;
suppose
A46: x is FinSeq-Location;
then x <> IC SCM+FSA by SCMFSA_2:57;
then
A47: not x in dom Start-At(l,SCM+FSA) by A41,TARSKI:def 1;
IExec(I ";" J,p,s).x = IExec(J,p,IExec(I,p,s)).x
by A36,A46,SCMFSA_M:2;
hence
IExec(I ";" J,p,s).x = IncIC(IExec(J,p,IExec(I,p,s)),card I).x
by A47,FUNCT_4:11;
end;
suppose
A48: x = IC SCM+FSA;
then x in {IC SCM+FSA} by TARSKI:def 1;
then
A49: x in dom Start-At(l,SCM+FSA) by FUNCOP_1:13;
thus IExec(I ";" J,p,s).x = (Start-At(l,SCM+FSA)).IC SCM+FSA
by A40,A48,FUNCOP_1:72
.= IncIC(IExec(J,p,IExec(I,p,s)),card I).x by A48,A49,FUNCT_4:13;
end;
end;
dom IExec(I ";" J,p,s) = the carrier of SCM+FSA by PARTFUN1:def 2
.= dom IncIC(IExec(J,p,IExec(I,p,s)),card I) by PARTFUN1:def 2;
hence thesis by A42,FUNCT_1:2;
end;
end;
registration
let i be sequential Instruction of SCM+FSA;
cluster Macro i -> InitHalting;
coherence;
end;
registration
let i be sequential Instruction of SCM+FSA,
J be parahalting really-closed Program of SCM+FSA;
cluster i ";" J -> InitHalting;
coherence;
end;
registration
let i be keeping_0 sequential Instruction of SCM+FSA,
J be InitHalting really-closed Program of SCM+FSA;
cluster i ";" J -> InitHalting;
coherence;
end;
registration
let I, J be keepInt0_1 really-closed Program of SCM+FSA;
cluster I ";" J -> keepInt0_1;
coherence
proof
let s be State of SCM+FSA;
assume
A1: iS c= s;
then
A2: Initialized s = s by FUNCT_4:98;
let p;
assume
A3: I ";" J c= p;
then
A4: p +* (I ";" J) = p by FUNCT_4:98;
A5: I c= p +* I by FUNCT_4:25;
A6: iS c= Initialized s by FUNCT_4:25;
per cases;
suppose
A7: p+*I halts_on Initialized s;
let k be Nat;
A8: Initialized s = s by A1,FUNCT_4:98;
per cases;
suppose
A9: k <= LifeSpan(p+*I,Initialized s);
Comput(p +* I, (Initialized s),k).intloc 0 = 1 by Def2,A5,A6;
hence ::thesis
(Comput(p,s,k)).intloc 0 = 1 by A2,A7,A9,Th12,A4;
end;
suppose
A10: k > LifeSpan(p+*I,Initialized s);
set LS = LifeSpan(p+*I,Initialized s);
consider pp being Element of NAT such that
A11: k = LS + pp and
A12: 1 <= pp by A10,FINSEQ_4:84;
consider r being Nat such that
A13: pp = 1 + r by A12,NAT_1:10;
reconsider r as Element of NAT by ORDINAL1:def 12;
set Rr = Comput(p +* I +* J,
Result(p +* I,s) +*iS,r);
set Sr = Start-At (IC Comput(p +* I +* J,
(Result(p +* I,s) +*iS
),r) + card I, SCM+FSA);
A14: iS c=Result(p +* I,s) +*iS
by FUNCT_4:25;
J c= p +* I +* J by FUNCT_4:25;
then
A15: Comput(p +* I +* J,
Result(p +* I,s) +*iS,r).intloc 0 = 1
by Def2,A14;
dom Sr = {IC SCM+FSA} & intloc 0 <> IC SCM+FSA by FUNCOP_1:13
,SCMFSA_2:56;
then
A16: not intloc 0 in dom Sr by TARSKI:def 1;
(Rr +* Sr) = Comput(p +* (I ";" J), (s),LS+1+r)
by A1,A7,A8,Th14,A3;
hence thesis by A11,A13,A15,A16,A4,FUNCT_4:11;
end;
end;
suppose
A17: not p+*I halts_on Initialized s;
let k be Nat;
Comput(p +* I, (Initialized s),k).intloc 0 = 1 by Def2,A5,A6;
hence thesis by A2,A4,A17,Th15;
end;
end;
end;
registration
let j be keeping_0 sequential Instruction of SCM+FSA,
I be keepInt0_1 InitHalting really-closed Program of SCM+FSA;
cluster I ";" j -> InitHalting keepInt0_1;
coherence;
end;
registration
let i be keeping_0 sequential Instruction of SCM+FSA,
J be keepInt0_1 InitHalting really-closed Program of SCM+FSA;
cluster i ";" J -> InitHalting keepInt0_1;
coherence;
end;
registration
let j be sequential Instruction of SCM+FSA,
I be parahalting really-closed Program of SCM+FSA;
cluster I ";" j -> InitHalting;
coherence;
end;
registration
let i,j be sequential Instruction of SCM+FSA;
cluster i ";" j -> InitHalting;
coherence;
end;
theorem Th18:
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J being InitHalting really-closed Program of SCM+FSA
holds IExec(I ";" J,p,s).a = IExec(J,p,IExec(I,p,s)).a
proof
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J be InitHalting really-closed Program of SCM+FSA;
IExec(I ";" J,p,s)
= IncIC(IExec(J,p,IExec(I,p,s)),card I) & not a in dom
Start-At (IC IExec(J,p,IExec(I,p,s)) + card I, SCM+FSA) by Th17,SCMFSA_2:102;
hence thesis by FUNCT_4:11;
end;
theorem Th19:
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J being InitHalting really-closed Program of SCM+FSA
holds IExec(I ";" J,p,s).f = IExec(J,p,IExec(I,p,s)).f
proof
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA,
J be InitHalting really-closed Program of SCM+FSA;
IExec(I ";" J,p,s) = IncIC(IExec(J,p,IExec(I,p,s)),card I) & not f in dom
Start-At (IC IExec(J,p,IExec(I,p,s)) + card I, SCM+FSA) by Th17,SCMFSA_2:103;
hence thesis by FUNCT_4:11;
end;
theorem Th20:
for I be keepInt0_1 InitHalting Program of SCM+FSA, s be State
of SCM+FSA holds DataPart(Initialized IExec(I,p,s)) = DataPart IExec(I,p,s)
proof
set IF = Data-Locations SCM+FSA;
let I be keepInt0_1 InitHalting Program of SCM+FSA, s be State of SCM+FSA;
set IE = IExec(I,p,s);
now
A1: dom (Initialized IE) = the carrier of SCM+FSA by PARTFUN1:def 2;
A2: dom Initialized IE
= Data-Locations SCM+FSA \/ {IC SCM+FSA} by MEMSTR_0:13;
A3: dom IE = the carrier of SCM+FSA by PARTFUN1:def 2;
hence dom DataPart Initialized IE = dom IE /\ IF by A1,RELAT_1:61;
then
A4: dom DataPart Initialized IE = Data-Locations SCM+FSA
by A1,A3,A2,XBOOLE_1:21;
let x be object;
assume
A5: x in dom DataPart Initialized IE;
per cases by A5,A4,SCMFSA_2:100,XBOOLE_0:def 3;
suppose
x in Int-Locations;
then reconsider x9 = x as Int-Location by AMI_2:def 16;
hereby
per cases;
suppose
A6: x9 is read-write;
thus (DataPart Initialized IE).x = (Initialized IE).x by A5,A4,
FUNCT_1:49
.= IE.x by A6,SCMFSA_M:37;
end;
suppose
x9 is read-only;
then
A7: x9 = intloc 0;
thus (DataPart Initialized IE).x = (Initialized IE).x9 by A5,A4,
FUNCT_1:49
.= 1 by A7,SCMFSA_M:9
.= IE.x by A7,Th7;
end;
end;
end;
suppose
x in FinSeq-Locations;
then reconsider x9 = x as FinSeq-Location by SCMFSA_2:def 5;
thus (DataPart Initialized IE).x = (Initialized IE).x9
by A5,A4,FUNCT_1:49
.= IE.x by SCMFSA_M:37;
end;
end;
hence thesis by FUNCT_1:46;
end;
theorem Th21:
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
j being sequential Instruction of SCM+FSA
holds IExec(I ";" j,p,s).a = Exec(j,IExec(I,p,s)).a
proof
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA,
j be sequential Instruction of SCM+FSA;
set Mj = Macro j;
set SA = Start-At (IC IExec(Mj,p,IExec(I,p,s)) + card I, SCM+FSA);
A1: not a in dom SA by SCMFSA_2:102;
A2: DataPart Initialized IExec(I,p,s) = DataPart IExec(I,p,s) by Th20;
a in Int-Locations by AMI_2:def 16;
then
A3: a in Data-Locations SCM+FSA by SCMFSA_2:100,XBOOLE_0:def 3;
thus IExec(I ";" j,p,s).a = IncIC(IExec(Mj,p,IExec(I,p,s)),card I).a by Th17
.= IExec(Mj,p,IExec(I,p,s)).a by A1,FUNCT_4:11
.= ( Exec(j, Initialized IExec(I,p,s))).a by SCMFSA6C:5
.= (DataPart Exec(j, Initialized IExec(I,p,s))).a by A3,FUNCT_1:49
.= (DataPart Exec(j, IExec(I,p,s))).a by A2,SCMFSA6C:4
.= Exec(j, IExec(I,p,s)).a by A3,FUNCT_1:49;
end;
theorem
for I being keepInt0_1 InitHalting really-closed Program of SCM+FSA,
j being sequential Instruction of SCM+FSA
holds IExec(I ";" j,p,s).f = Exec(j,IExec(I,p,s)).f
proof
let I be keepInt0_1 InitHalting really-closed Program of SCM+FSA,
j be sequential Instruction of SCM+FSA;
set Mj = Macro j;
set SA = Start-At (IC IExec(Mj,p,IExec(I,p,s)) + card I, SCM+FSA);
A1: not f in dom SA by SCMFSA_2:103;
A2: DataPart Initialized IExec(I,p,s) = DataPart IExec(I,p,s) by Th20;
f in FinSeq-Locations by SCMFSA_2:def 5;
then
A3: f in Data-Locations SCM+FSA by SCMFSA_2:100,XBOOLE_0:def 3;
thus IExec(I ";" j,p,s).f = IncIC(IExec(Mj,p,IExec(I,p,s)),card I).f by Th17
.= IExec(Mj,p,IExec(I,p,s)).f by A1,FUNCT_4:11
.= ( Exec(j, Initialized IExec(I,p,s))).f by SCMFSA6C:5
.= (DataPart Exec(j, Initialized IExec(I,p,s))).f by A3,FUNCT_1:49
.= (DataPart Exec(j, IExec(I,p,s))).f by A2,SCMFSA6C:4
.= Exec(j, IExec(I,p,s)).f by A3,FUNCT_1:49;
end;
definition
let I be Program of SCM+FSA;
let s be State of SCM+FSA;
let p;
pred I is_halting_onInit s,p means
p+*I halts_on Initialized s;
end;
::$CD
::$CT
theorem Th23:
for I being Program of SCM+FSA holds I is InitHalting iff for s
being State of SCM+FSA,p holds I is_halting_onInit s,p
proof
let I be Program of SCM+FSA;
hereby
assume
A1: I is InitHalting;
let s be State of SCM+FSA;
let p;
A2: I c= p+*I by FUNCT_4:25;
iS c= Initialized s by FUNCT_4:25;
then p+*I halts_on Initialized s by A2,A1;
hence I is_halting_onInit s,p;
end;
assume
A3: for s being State of SCM+FSA,p holds I is_halting_onInit s,p;
now
let s be State of SCM+FSA;
assume iS c= s;
then
A4: s = Initialized s by FUNCT_4:98;
let p;
assume I c= p;
then
A5: p +* I = p by FUNCT_4:98;
I is_halting_onInit s,p by A3;
hence p halts_on s by A4,A5;
end;
hence thesis;
end;
theorem Th24:
for s being State of SCM+FSA, I being really-closed Program of SCM+FSA, a
being Int-Location st I does not destroy a &
:::I is_closed_onInit s,p &
Initialize ((intloc 0) .--> 1) c= s & I c= p
holds for k being Nat holds Comput(p,s,k).a = s.a
proof
let s be State of SCM+FSA,
I be really-closed Program of SCM+FSA,a be Int-Location;
assume
A1: I does not destroy a;
defpred P[Nat] means Comput(p,s,$1).a = s.a;
assume iS c= s;
then
A2: Initialized s = s by FUNCT_4:98;
assume
A3: I c= p;
A4: now
let k be Nat;
assume
A5: P[k];
set l = IC Comput(p,s,k);
IC s = 0 by A2,MEMSTR_0:def 11;
then IC s in dom I by AFINSQ_1:65;
then
A6: l in dom I by AMISTD_1:21,A3;
then p.l = I.l by A3,GRFUNC_1:2;
then p.l in rng I by A6,FUNCT_1:def 3;
then
A7: p.l does not destroy a by A1;
Comput(p, s,k + 1).a = (Following(p,
Comput(p,s,k))).a by EXTPRO_1:3
.= Exec(p.l,Comput(p,s,k)).a by PBOOLE:143
.= s.a by A5,A7,SCMFSA7B:20;
hence P[k+1];
end;
A8: P[0];
thus for k being Nat holds P[k] from NAT_1:sch 2(A8,A4);
end;
registration
cluster InitHalting good for Program of SCM+FSA;
existence
proof
take Stop SCM+FSA;
thus thesis;
end;
end;
registration
cluster really-closed good -> keepInt0_1 for Program of SCM+FSA;
correctness
proof
let I be Program of SCM+FSA;
assume
A1: I is really-closed good;
now
let s be State of SCM+FSA;
assume
A2: iS c= s;
let p;
assume
A3: I c= p;
let k be Nat;
thus Comput(p,s,k).intloc 0 = s.intloc 0 by A1,A2,Th24,A3
.=1 by A2,SCMFSA_M:30;
end;
hence thesis;
end;
end;
registration
cluster Stop SCM+FSA -> InitHalting good;
coherence;
end;
theorem
for s being State of SCM+FSA, i being keeping_0 sequential
Instruction of SCM+FSA, J being InitHalting really-closed Program of SCM+FSA,
a being
Int-Location holds IExec(i ";" J,p,s).a
= IExec(J,p,Exec(i,Initialized s)).a
proof
let s be State of SCM+FSA;
let i be keeping_0 sequential Instruction of SCM+FSA;
let J be InitHalting really-closed Program of SCM+FSA;
let a be Int-Location;
thus IExec(i ";" J,p,s).a
= IExec(J,p,IExec(Macro i,p,s)).a by Th18
.= IExec(J,p,Exec(i,Initialized s)).a by SCMFSA6C:5;
end;
theorem
for s being State of SCM+FSA, i being keeping_0 sequential
Instruction of SCM+FSA, J being InitHalting really-closed Program of SCM+FSA,
f being
FinSeq-Location holds IExec(i ";" J,p,s).f
= IExec(J,p,Exec(i,Initialized s)).f
proof
let s be State of SCM+FSA;
let i be keeping_0 sequential Instruction of SCM+FSA;
let J be InitHalting really-closed Program of SCM+FSA;
let f be FinSeq-Location;
thus IExec(i ";" J,p,s).f = IExec(J,p,IExec(Macro i,p,s)).f by Th19
.= IExec(J,p,Exec(i,Initialized s)).f by SCMFSA6C:5;
end;
::$CT
theorem Th27:
for s being State of SCM+FSA, I being Program of SCM+FSA holds I
is_halting_onInit s,p iff I is_halting_on Initialized s,p
by MEMSTR_0:44;
theorem
for I be Program of SCM+FSA, s be State of SCM+FSA holds IExec(I,p,s) =
IExec(I,p,Initialized s)
proof
let I be Program of SCM+FSA,s be State of SCM+FSA;
set sp= s|NAT;
thus IExec(I,p,s)
= Result(p+*I,Initialized Initialized s) by SCMFSA6B:def 1
.= IExec(I,p,Initialized s) by SCMFSA6B:def 1;
end;
theorem Th29:
for s being State of SCM+FSA,
I being really-closed MacroInstruction of SCM+FSA,
J being MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a = 0 &
:::I is_closed_onInit s,p &
I is_halting_onInit s,p holds
:::if=0(a,I,J) is_closed_onInit s,p &
if=0(a,I,J) is_halting_onInit s,p
proof
let s be State of SCM+FSA;
let I be really-closed MacroInstruction of SCM+FSA;
let J be MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
set Is = Initialized s;
assume s.a = 0;
then
A1: Is.a =0 by SCMFSA_M:37;
assume I is_halting_onInit s,p;
then I is_halting_on Is,p by Th27;
then
if=0(a,I,J) is_halting_on Is,p by A1,SCMFSA8B:13;
hence thesis by Th27;
end;
theorem Th30:
for s being State of SCM+FSA,
I being really-closed MacroInstruction of SCM+FSA,
J being MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a = 0 &
I is_halting_onInit s,p
holds IExec(if=0(a,I,J),p,s)
= IExec(I,p,s) +* Start-At( (card I + card J + 3),SCM+FSA)
proof
let s be State of SCM+FSA;
let I be really-closed MacroInstruction of SCM+FSA;
let J be MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
assume
A1: s.a = 0;
set Is = Initialized s;
assume I is_halting_onInit s,p;
then I is_halting_on Is,p by Th27;
hence thesis by A1,SCMFSA8B:14;
end;
theorem Th31:
for s being State of SCM+FSA,
I,J being really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a <> 0
:::& J is_closed_onInit s,p
& J is_halting_onInit s,p
holds
:::if=0(a,I,J) is_closed_onInit s,p &
if=0(a,I,J)
is_halting_onInit s,p
proof
let s be State of SCM+FSA;
let I,J be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
set Is = Initialized s;
assume s.a <> 0;
then
A1: Is.a <> 0 by SCMFSA_M:37;
assume J is_halting_onInit s,p;
then J is_halting_on Is,p by Th27;
then
if=0(a,I,J) is_halting_on Is,p by A1,SCMFSA8B:15;
hence thesis by Th27;
end;
theorem Th32:
for I,J being really-closed MacroInstruction of SCM+FSA, a being read-write
Int-Location holds for s being State of SCM+FSA st s.a <> 0 &
:::Jis_closed_onInit s,p &
J is_halting_onInit s,p
holds IExec(if=0(a,I,J),p,s)
= IExec(J,p,s) +* Start-At((card I + card J + 3),SCM+FSA)
proof
let I,J be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
let s be State of SCM+FSA;
assume
A1: s.a <> 0;
set Is = Initialized s;
assume J is_halting_onInit s,p;
then J is_halting_on Is,p by Th27;
hence thesis by A1,SCMFSA8B:16;
end;
theorem Th33:
for s being State of SCM+FSA,
I,J being really-closed InitHalting MacroInstruction of
SCM+FSA, a being read-write Int-Location holds if=0(a,I,J) is InitHalting & (s.
a = 0 implies IExec(if=0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((card I +
card J + 3),SCM+FSA)) &
(s.a <> 0 implies IExec(if=0(a,I,J),p,s) = IExec(J,p,s) +* Start-At(
(card I + card J + 3),SCM+FSA))
proof
let s be State of SCM+FSA;
let I,J be InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
now
let s be State of SCM+FSA;
assume iS c= s;
then
A1: s = Initialized s by FUNCT_4:98;
let p;
assume if=0(a,I,J) c= p;
then
A2: p = p +* if=0(a,I,J) by FUNCT_4:98;
A3:
J is_halting_onInit s,p by Th23;
A4:
I is_halting_onInit s,p by Th23;
per cases;
suppose
s.a = 0;
then if=0(a,I,J) is_halting_onInit s,p by A4,Th29;
hence p halts_on s by A1,A2;
end;
suppose
s.a <> 0;
then if=0(a,I,J) is_halting_onInit s,p by A3,Th31;
hence p halts_on s by A1,A2;
end;
end;
hence if=0(a,I,J) is InitHalting;
I is_halting_onInit s,p by Th23;
hence s.a = 0 implies IExec(if=0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((
card I + card J + 3),SCM+FSA) by Th30;
J is_halting_onInit s,p by Th23;
hence thesis by Th32;
end;
theorem
for s being State of SCM+FSA,
I,J being InitHalting really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location holds IC IExec(if=0(a,I,J),p,s) = (card
I + card J + 3) & (s.a = 0 implies ((for d being Int-Location
holds IExec(if=0(a,I,J),p,s).d = IExec(I,p,s).d) &
for f being FinSeq-Location
holds IExec(if=0(a,I,J),p,s).f = IExec(I,p,s).f)) & (s.a <> 0 implies
((for d being Int-Location holds
IExec(if=0(a,I,J),p,s).d = IExec(J,p,s).d) &
for f being FinSeq-Location holds
IExec(if=0(a,I,J),p,s).f = IExec(J,p,s).f))
proof
let s be State of SCM+FSA;
let I,J be InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
hereby
per cases;
suppose
s.a = 0;
then
IExec(if=0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((card I + card
J + 3),SCM+FSA) by Th33;
hence IC IExec(if=0(a,I,J),p,s) = (card I + card J + 3) by FUNCT_4:113;
end;
suppose
s.a <> 0;
then
IExec(if=0(a,I,J),p,s) = IExec(J,p,s) +* Start-At((card I + card
J + 3),SCM+FSA) by Th33;
hence IC IExec(if=0(a,I,J),p,s) = (card I + card J + 3) by FUNCT_4:113;
end;
end;
hereby
assume s.a = 0;
then
A1: IExec(if=0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((card I + card J
+ 3),SCM+FSA) by Th33;
hereby
let d be Int-Location;
not d in dom Start-At((card I + card J + 3),SCM+FSA)
by SCMFSA_2:102;
hence IExec(if=0(a,I,J),p,s).d = IExec(I,p,s).d by A1,FUNCT_4:11;
end;
let f be FinSeq-Location;
not f in dom Start-At((card I + card J + 3),SCM+FSA)
by SCMFSA_2:103;
hence IExec(if=0(a,I,J),p,s).f = IExec(I,p,s).f by A1,FUNCT_4:11;
end;
assume s.a <> 0;
then
A2: IExec(if=0(a,I,J),p,s) = IExec(J,p,s) +* Start-At((card I + card J +
3),SCM+FSA) by Th33;
hereby
let d be Int-Location;
not d in dom Start-At((card I + card J + 3),SCM+FSA) by SCMFSA_2:102;
hence IExec(if=0(a,I,J),p,s).d = IExec(J,p,s).d by A2,FUNCT_4:11;
end;
let f be FinSeq-Location;
not f in dom Start-At((card I + card J + 3),SCM+FSA) by SCMFSA_2:103;
hence thesis by A2,FUNCT_4:11;
end;
theorem Th35:
for s being State of SCM+FSA,
I,J being really-closed MacroInstruction of SCM+FSA, a
being read-write Int-Location st s.a > 0 &
:::I is_closed_onInit s,p &
I
is_halting_onInit s,p holds
:::if>0(a,I,J) is_closed_onInit s,p &
if>0(a,I,J)
is_halting_onInit s,p
proof
let s be State of SCM+FSA;
let I,J be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
set Is = Initialized s;
assume s.a > 0;
then
A1: Is.a >0 by SCMFSA_M:37;
assume I is_halting_onInit s,p;
then I is_halting_on Is,p by Th27;
then
if>0(a,I,J) is_halting_on Is,p by A1,
SCMFSA8B:19;
hence thesis by Th27;
end;
theorem Th36:
for s being State of SCM+FSA,
I,J being really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a > 0 &
:::I is_closed_onInit s,p &
I
is_halting_onInit s,p holds IExec(if>0(a,I,J),p,s)
= IExec(I,p,s) +* Start-At((card I + card J + 3),SCM+FSA)
proof
let s be State of SCM+FSA;
let I,J be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
assume
A1: s.a > 0;
set Is = Initialized s;
assume I is_halting_onInit s,p;
then I is_halting_on Is,p by Th27;
hence thesis by A1,SCMFSA8B:20;
end;
theorem Th37:
for s being State of SCM+FSA,
I,J being really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a <= 0 &
:::J is_closed_onInit s,p &
J
is_halting_onInit s,p holds
:::if>0(a,I,J) is_closed_onInit s,p &
if>0(a,I,J) is_halting_onInit s,p
proof
let s be State of SCM+FSA;
let I,J be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
set Is = Initialized s;
assume s.a <= 0;
then
A1: Is.a <= 0 by SCMFSA_M:37;
assume J is_halting_onInit s,p;
then J is_halting_on Is,p by Th27;
then
if>0(a,I,J) is_halting_on Is,p by A1,
SCMFSA8B:21;
hence thesis by Th27;
end;
theorem Th38:
for I,J being really-closed MacroInstruction of SCM+FSA, a being read-write
Int-Location holds for s being State of SCM+FSA st s.a <= 0 &
:::Jis_closed_onInit s,p &
J is_halting_onInit s,p
holds IExec(if>0(a,I,J),p,s)
= IExec(J,p,s) +* Start-At((card I + card J + 3),SCM+FSA)
proof
let I,J be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
let s be State of SCM+FSA;
assume
A1: s.a <= 0;
set Is = Initialized s;
assume J is_halting_onInit s,p;
then J is_halting_on Is,p by Th27;
hence thesis by A1,SCMFSA8B:22;
end;
theorem Th39:
for s being State of SCM+FSA,
I,J being InitHalting really-closed MacroInstruction of
SCM+FSA, a being read-write Int-Location holds if>0(a,I,J) is InitHalting & (s.
a > 0 implies IExec(if>0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((card I +
card J + 3),SCM+FSA)) &
(s.a <= 0 implies IExec(if>0(a,I,J),p,s) = IExec(J,p,s) +* Start-At(
(card I + card J + 3),SCM+FSA))
proof
let s be State of SCM+FSA;
let I,J be InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
now
let s be State of SCM+FSA;
assume iS c= s;
then
A1: s = Initialized s by FUNCT_4:98;
let p;
assume if>0(a,I,J) c= p;
then
A2: p = p +* if>0(a,I,J) by FUNCT_4:98;
A3:
:::J is_closed_onInit s,p &
J is_halting_onInit s,p by Th23;
A4:
:::I is_closed_onInit s,p &
I is_halting_onInit s,p by Th23;
per cases;
suppose
s.a > 0;
then if>0(a,I,J) is_halting_onInit s,p by A4,Th35;
hence p halts_on s by A1,A2;
end;
suppose
s.a <= 0;
then if>0(a,I,J) is_halting_onInit s,p by A3,Th37;
hence p halts_on s by A1,A2;
end;
end;
hence if>0(a,I,J) is InitHalting;
I is_halting_onInit s,p by Th23;
hence s.a > 0 implies IExec(if>0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((
card I + card J + 3),SCM+FSA) by Th36;
J is_halting_onInit s,p by Th23;
hence thesis by Th38;
end;
theorem
for s being State of SCM+FSA,
I,J being InitHalting really-closed MacroInstruction of SCM+FSA
, a being read-write Int-Location holds IC IExec(if>0(a,I,J),p,s) = (card
I + card J + 3) & (s.a > 0 implies ((for d being Int-Location
holds IExec(if>0(a,I,J),p,s).d = IExec(I,p,s).d) &
for f being FinSeq-Location
holds IExec(if>0(a,I,J),p,s).f
= IExec(I,p,s).f)) & (s.a <= 0 implies ((for d being Int-Location
holds
IExec(if>0(a,I,J),p,s).d = IExec(J,p,s).d) & for f being FinSeq-Location
holds
IExec(if>0(a,I,J),p,s).f = IExec(J,p,s).f))
proof
let s be State of SCM+FSA;
let I,J be InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
hereby
per cases;
suppose
s.a > 0;
then
IExec(if>0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((card I + card
J + 3),SCM+FSA) by Th39;
hence IC IExec(if>0(a,I,J),p,s) = (card I + card J + 3) by FUNCT_4:113;
end;
suppose
s.a <= 0;
then
IExec(if>0(a,I,J),p,s) = IExec(J,p,s) +* Start-At((card I + card
J + 3),SCM+FSA) by Th39;
hence IC IExec(if>0(a,I,J),p,s) = (card I + card J + 3) by FUNCT_4:113;
end;
end;
hereby
assume s.a > 0;
then
A1: IExec(if>0(a,I,J),p,s) = IExec(I,p,s) +* Start-At((card I + card J
+ 3),SCM+FSA) by Th39;
hereby
let d be Int-Location;
not d in dom Start-At((card I + card J + 3),SCM+FSA)
by SCMFSA_2:102;
hence IExec(if>0(a,I,J),p,s).d = IExec(I,p,s).d by A1,FUNCT_4:11;
end;
let f be FinSeq-Location;
not f in dom Start-At((card I + card J + 3),SCM+FSA) by SCMFSA_2:103;
hence IExec(if>0(a,I,J),p,s).f = IExec(I,p,s).f by A1,FUNCT_4:11;
end;
assume s.a <= 0;
then
A2: IExec(if>0(a,I,J),p,s) = IExec(J,p,s) +* Start-At((card I + card J +
3),SCM+FSA) by Th39;
hereby
let d be Int-Location;
not d in dom Start-At((card I + card J + 3),SCM+FSA) by SCMFSA_2:102;
hence IExec(if>0(a,I,J),p,s).d = IExec(J,p,s).d by A2,FUNCT_4:11;
end;
let f be FinSeq-Location;
not f in dom Start-At((card I + card J + 3),SCM+FSA) by SCMFSA_2:103;
hence thesis by A2,FUNCT_4:11;
end;
::$CT 4
registration
let I,J be InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
cluster if=0(a,I,J) -> InitHalting;
correctness by Th33;
cluster if>0(a,I,J) -> InitHalting;
correctness by Th39;
:: cluster if<0(a,I,J) -> InitHalting;
:: correctness by Th46;
end;
theorem Th41:
for I being Program of SCM+FSA holds I is InitHalting iff for s
being State of SCM+FSA,p holds I is_halting_on Initialized s,p
proof
let I be Program of SCM+FSA;
thus I is InitHalting implies
for s be State of SCM+FSA,p holds I is_halting_on Initialized s,p
by Th23,Th27;
assume for s being State of SCM+FSA,p holds I is_halting_on Initialized s,p;
then for s be State of SCM+FSA,p holds I is_halting_onInit s,p by Th27;
hence thesis by Th23;
end;
::$CT
theorem Th42:
for s being State of SCM+FSA, I being InitHalting Program of
SCM+FSA, a being read-write Int-Location holds IExec(I,p,s).a
= Comput(p +* I, Initialize Initialized s,
LifeSpan(p +* I,Initialize Initialized s)).a
proof
let s be State of SCM+FSA,I be InitHalting Program of SCM+FSA;
let a be read-write Int-Location;
I is_halting_on Initialized s,p by Th41;
hence thesis by SCMFSA8C:58;
end;
theorem Th43:
for s being State of SCM+FSA, I being InitHalting really-closed Program of
SCM+FSA, a being Int-Location,k being Element of NAT st I does not destroy a
holds IExec(I,p,s).a = Comput(p +* I,
Initialize Initialized s,k).a
proof
let s be State of SCM+FSA,
I be InitHalting really-closed Program of SCM+FSA;
let a be Int-Location,k be Element of NAT;
assume
A1: I does not destroy a;
I is_halting_on Initialized s,p by Th41;
hence thesis by A1,SCMFSA8C:60;
end;
set A = NAT;
set D = Data-Locations SCM+FSA;
theorem Th44:
for s being State of SCM+FSA, I being InitHalting really-closed Program of
SCM+FSA, a being Int-Location st I does not destroy a
holds IExec(I,p,s).a = (Initialized s).a
proof
let s be State of SCM+FSA;
let I be InitHalting really-closed Program of SCM+FSA;
let a be Int-Location;
A1: Initialized s
= s +* (Initialize ((intloc 0) .--> 1)+*(SA0))
.= Initialized s+*SA0 by FUNCT_4:14;
assume I does not destroy a;
hence
IExec(I,p,s).a = Comput(p +* I,
Initialize Initialized s,0).a by Th43
.= (Initialized s).a by A1;
end;
theorem
for s be State of SCM+FSA,
I be keepInt0_1 InitHalting really-closed Program of
SCM+FSA, a being read-write Int-Location st I does not destroy a holds
Comput(p +* (I ";" SubFrom(a,intloc 0)),
Initialize Initialized s,
LifeSpan(p +* (I ";" SubFrom(a,intloc 0)),
Initialize Initialized s)).a
= s.a - 1
proof
let s be State of SCM+FSA,
I be keepInt0_1 InitHalting really-closed Program of SCM+FSA;
let a be read-write Int-Location;
assume
A1: I does not destroy a;
set s0 = Initialized s,
p0 = p;
set s1 = Initialize s0,
p1 = p0 +* (I ";" SubFrom(a,intloc 0));
A2: a <> IC SCM+FSA by SCMFSA_2:56;
dom SA0 = {IC SCM+FSA} by FUNCOP_1:13;
then
A3: not a in dom SA0 by A2,TARSKI:def 1;
IExec(I ";" SubFrom(a,intloc 0),p,s).a
= Exec(SubFrom(a,intloc 0),IExec(I,p,s)).a by Th21
.= IExec(I,p,s).a - IExec(I,p,s).intloc 0 by SCMFSA_2:65
.= IExec(I,p,s).a - 1 by Th7
.= Comput(p0 +* I, (Initialize s0),0).a - 1
by A1,Th43
.= (Initialize s0).a - 1
.= s0.a - 1 by A3,FUNCT_4:11;
hence Comput(p1, s1,LifeSpan(p1,s1)).a = s0.a - 1 by Th42
.= s.a - 1 by SCMFSA_M:37;
end;
Lm3:
for s being 0-started State of SCM+FSA,
I being good InitHalting really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location
st I does not destroy a & s.intloc 0 = 1
for k being Nat holds StepTimes(a,I,p,s).k.intloc 0 = 1 &
I is_halting_on StepTimes(a,I,p,s).k, p+*Times(a,I)
proof
let s be 0-started State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA,
a be read-write Int-Location such that
A1: I does not destroy a and
A2: s.intloc 0 = 1;
defpred P[Nat] means StepTimes(a,I,p,s).$1.intloc 0 = 1 &
I is_halting_on StepTimes(a,I,p,s).$1, p+*Times(a,I);
A3: P[0]
proof
A4: StepTimes(a,I,p,s).0 = Initialized s by SCMFSA_9:def 5;
(Initialized s).intloc 0 = 1 by SCMFSA_M:5
.= s.intloc 0 by A2;
hence
A5: StepTimes(a,I,p,s).0.intloc 0 = 1 by A4,A2;
intloc 0 in dom(StepTimes(a,I,p,s).0) by SCMFSA_2:42;
then (intloc 0) .--> 1 c= StepTimes(a,I,p,s).0 by A5,FUNCOP_1:84;
then
A6: Initialize ((intloc 0) .--> 1) c= Initialize StepTimes(a,I,p,s).0
by FUNCT_4:123;
I c= p+*Times(a,I) +* I by FUNCT_4:25;
hence p+*Times(a,I) +* I halts_on Initialize StepTimes(a,I,p,s).0
by A6,Def1;
end;
A7: for k being Nat st P[k] holds P[k+1]
proof let k be Nat;
assume
A8: P[k];
thus
A9: StepTimes(a,I,p,s).(k+1).intloc 0 = 1 by A8,A1,SCMFSA9A:48;
intloc 0 in dom(StepTimes(a,I,p,s).(k+1)) by SCMFSA_2:42;
then (intloc 0) .--> 1 c= StepTimes(a,I,p,s).(k+1) by A9,FUNCOP_1:84;
then
A10: Initialize ((intloc 0) .--> 1) c= Initialize StepTimes(a,I,p,s).(k+1)
by FUNCT_4:123;
I c= p+*Times(a,I) +* I by FUNCT_4:25;
hence p+*Times(a,I) +* I halts_on Initialize StepTimes(a,I,p,s).(k+1)
by A10,Def1;
end;
thus for k being Nat holds P[k] from NAT_1:sch 2(A3,A7);
end;
::$CT 7
theorem
for s being 0-started State of SCM+FSA,
I being good InitHalting really-closed MacroInstruction of
SCM+FSA, a being read-write Int-Location
st I does not destroy a & s.intloc 0 = 1
holds Times(a,I) is_halting_on s,p
proof
let s be 0-started State of SCM+FSA;
let I be good InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
assume
A1: I does not destroy a;
assume
A2: s.intloc 0 = 1;
ProperTimesBody a, I, s, p
proof let k be Nat such that
k < s.a;
thus I is_halting_on StepTimes(a,I,p,s).k, p+*Times(a,I) by A1,A2,Lm3;
end;
hence thesis by A1,A2,SCMFSA9A:55;
end;
registration
let a be read-write Int-Location,I be good MacroInstruction of SCM+FSA;
cluster Times(a,I) -> good;
coherence;
end;
::$CT 2
theorem Th47:
for s being State of SCM+FSA,
I being good InitHalting really-closed MacroInstruction
of SCM+FSA, a being read-write Int-Location st s.intloc 0 = 1 & s.a <= 0 holds
DataPart IExec(Times(a,I),p,s) = DataPart s by SCMFSA9A:58;
reserve P,P1,P2,Q for Instruction-Sequence of SCM+FSA;
:: from SCMISORT
Lm4:
for s be State of SCM+FSA,I be InitHalting really-closed Program of SCM+FSA
st Initialize ((intloc 0) .--> 1) c= s & I c= P1 & I c= P2
for k be Nat
holds Comput(P1, s,k) = Comput(P2, s,k) &
CurInstr(P1,Comput(P1,s,k)) = CurInstr(P2,Comput(P2,s,k))
proof
let s be State of SCM+FSA,I be InitHalting really-closed Program of SCM+FSA;
assume that
A1: Initialize ((intloc 0) .--> 1) c= s and
A2: I c= P1 and
A3: I c= P2;
let k be Nat;
IC s = 0 by A1,MEMSTR_0:47;
then
A4: IC s in dom I by AFINSQ_1:65;
then
A5: IC Comput(P1,s,k) in dom I by A2,AMISTD_1:21;
A6: IC Comput(P2,s,k) in dom I by A3,AMISTD_1:21,A4;
for m being Nat st m < k holds IC(Comput(P2,s,m))
in dom I by A3,A4,AMISTD_1:21;
hence Comput(P1,s,k) = Comput(P2,s,k) by A2,A3,AMISTD_2:10;
then
A7: IC Comput(P1,s,k) = IC Comput(P2, s,k);
thus CurInstr(P2,Comput(P2,s,k))
= P2.IC Comput(P2, s,k) by PBOOLE:143
.= I.IC Comput(P2,s,k) by A6,A3,GRFUNC_1:2
.= P1.IC Comput(P1,s,k) by A7,A5,A2,GRFUNC_1:2
.= CurInstr(P1,Comput(P1,s,k)) by PBOOLE:143;
end;
Lm5: ::SCMFSA6B:29
for s be State of SCM+FSA,I be InitHalting really-closed Program of SCM+FSA
st Initialize ((intloc 0) .--> 1) c= s &
I c= P1 & I c= P2
holds LifeSpan(P1,s) = LifeSpan(P2,s) &
Result(P1,s) = Result(P2,s)
proof
let s be State of SCM+FSA,I be InitHalting really-closed Program of SCM+FSA;
assume that
A1: Initialize ((intloc 0) .--> 1) c= s and
A2: I c= P1 and
A3: I c= P2;
A4: P2 halts_on s by A1,A3,Def1;
A5: P1 halts_on s by A1,A2,Def1;
A6: now
let l be Nat;
assume
A7: CurInstr(P2,Comput(P2,s,l)) = halt SCM+FSA;
CurInstr(P1,Comput(P1,s,l))
= CurInstr(P2,Comput(P2,s,l)) by A1,Lm4,A2,A3;
hence LifeSpan(P1,s) <= l by A5,A7,EXTPRO_1:def 15;
end;
CurInstr(P2,
Comput(P2,s,LifeSpan(P1,s)))
= CurInstr(P1,Comput(P1,s,LifeSpan(P1,s))) by A1,Lm4,A2,A3
.= halt SCM+FSA by A5,EXTPRO_1:def 15;
hence
LifeSpan(P1,s) = LifeSpan(P2,s) by A6,A4,EXTPRO_1:def 15;
thus thesis by A1,Th6,A2,A3;
end;
Lm6:
for s being State of SCM+FSA,
I being really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a <= 0
holds while>0(a,I) is_halting_onInit s,P
proof
let s be State of SCM+FSA,I be really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
set s0=Initialized s;
assume s.a <= 0;
then
A1: s0.a <= 0 by SCMFSA_M:37;
while>0(a,I) is_halting_on s0,P by A1,SCMFSA_9:38;
hence thesis by Th27;
end;
Lm7: ::SCM_9_37
for s being State of SCM+FSA,
I be really-closed MacroInstruction of SCM+FSA,
a be read-write Int-Location st
I is_halting_onInit s,P & s.a >
0 holds IC Comput(P +* while>0(a,I), Initialized s,
LifeSpan(P +* I,Initialized s) + 2) = 0 &
DataPart Comput(P +* while>0(a,I), Initialized s,
LifeSpan(P +* I,Initialized s) + 2)
= DataPart Comput(P +* I, Initialized s,LifeSpan(P +* I,Initialized s))
proof
let s be State of SCM+FSA,
I be really-closed MacroInstruction of SCM+FSA,
a be read-write Int-Location;
set D = Data-Locations SCM+FSA;
set s0=Initialized s;
set s1 = Initialize s0,
P1 = P +* while>0(a,I), PI = P +* I,
s2 = Comput(P1, s1,1), i = a >0_goto 3;
A1: while>0(a,I) c= P1 by FUNCT_4:25;
defpred P[Nat] means $1 <= LifeSpan(PI,s1) implies
IC Comput(P1, s1,1 + $1) = IC Comput(PI, s1,$1) + 3 &
DataPart Comput(P1, s1,1 + $1) = DataPart Comput(PI, s1,$1);
set loc4= card I + 2;
set s3= Comput(P1, s1,1+LifeSpan(PI,s1)+1);
A2: Initialize s0
= Initialize Initialized s
.= Initialize Initialized s
.= Initialized s by MEMSTR_0:44;
assume I is_halting_onInit s,P;
then
A3: P +* I halts_on Initialized s;
A4: I is_halting_on s0,P by A3,A2;
A5: now
let k be Nat;
assume
A6: P[k];
now
A7: k + 0 < k + 1 by XREAL_1:6;
assume k + 1 <= LifeSpan(PI,s1);
then k < LifeSpan(PI,s1) by A7,XXREAL_0:2;
hence IC Comput(P1, s1,1 + k+1) = IC Comput(PI, s1,k+1) + 3 &
DataPart Comput(P1, s1,1 + k+1) = DataPart Comput(PI, s1,k+1)
by A4,A6,SCMFSA_9:39;
end;
hence P[k + 1];
end;
0 in dom while>0(a,I) by AFINSQ_1:65;
then
A8: P1. 0 = while>0(a,I). 0 by A1,GRFUNC_1:2
.= i by SCMFSA_X:10;
IC SCM+FSA in dom Start-At(0,SCM+FSA) by MEMSTR_0:15;
then
A9: IC s1 = IC(Start-At(0,SCM+FSA)) by FUNCT_4:13
.= 0 by FUNCOP_1:72;
A10: Comput(P1, s1,0 + 1) = Following(P1,Comput(P1,s1,0)) by EXTPRO_1:3
.= Following(P1,s1)
.= Exec(i,s1) by A9,A8,PBOOLE:143;
then
A11: for f be FinSeq-Location holds s2.f = s1.f by SCMFSA_2:71;
for c be Int-Location holds s2.c = s1.c by A10,SCMFSA_2:71;
then
A12: DataPart s2 = DataPart s1 by A11,SCMFSA_M:2
.= DataPart s1;
set s4= Comput(P1, s1,1+LifeSpan(PI,s1)+1);
set s2= Comput(P1, s1,1 + LifeSpan(PI,s1));
not a in dom Start-At(0,SCM+FSA) by SCMFSA_2:102;
then
A13: s1.a = s0.a by FUNCT_4:11;
assume s.a > 0;
then
A14: s0.a > 0 by SCMFSA_M:37;
A15: P[ 0]
proof
assume 0 <= LifeSpan(PI,s1);
A16: IC SCM+FSA in dom (Start-At(0,SCM+FSA)) by MEMSTR_0:15;
IC Comput(PI, s1,0) = IC s1
.= IC(Start-At(0,SCM+FSA)) by A16,FUNCT_4:13
.= 0 by FUNCOP_1:72;
hence thesis by A14,A10,A13,A12,SCMFSA_2:71;
end;
for k being Nat holds P[k] from NAT_1:sch 2(A15,A5);
then
A17: P[LifeSpan(PI,s1)];
A18: s3 = Following(P1,s2) by EXTPRO_1:3
.= Exec(goto 0,s2) by A4,A17,SCMFSA_9:40;
A19: s4 = Exec(goto 0,s2) by A18;
then
A20: for f be FinSeq-Location holds s4.f = s2.f by SCMFSA_2:69;
for c be Int-Location holds s3.c = s2.c by A18,SCMFSA_2:69;
then
A21: DataPart s3 = DataPart s2 by A20,SCMFSA_M:2;
A22: Initialized s = Initialize Initialized s by MEMSTR_0:44;
Comput(P +* while>0(a,I), Initialized s, LifeSpan(P +* I,Initialized s) + 2)
=s4 by A22;
hence IC Comput(P +* while>0(a,I), Initialized s,
LifeSpan(P +* I,Initialized s) + 2) = 0 by A19,SCMFSA_2:69;
A23: s1 = Initialized s by MEMSTR_0:44;
thus DataPart Comput(P +* while>0(a,I), Initialized s,
LifeSpan(P +* I,Initialized s) + 2)
= DataPart Comput(P +* I, Initialized s,LifeSpan(P +* I,Initialized s))
by A23,A17,A21;
end;
Lm8:
for s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of
SCM+FSA, a be read-write Int-Location st s.a > 0 & while>0(a,I) is InitHalting
holds DataPart IExec(while>0(a,I),P,s) =
DataPart IExec(while>0(a,I),P,IExec(I,P,s))
proof
let s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA, a be
read-write Int-Location;
set D = Data-Locations SCM+FSA;
assume that
A1: s.a > 0 and
A2: while>0(a,I) is InitHalting;
set sI = Initialized s,
PI = P +* I,
PW = P +* while>0(a,I),
s3 = Initialized Comput(PI, sI,LifeSpan(PI,sI)),
P3 = PI +* while>0(a,I),
m1 = LifeSpan(PI,sI), m3 = LifeSpan(P3,s3);
A3: I c= PI by FUNCT_4:25;
A4: while>0(a,I) c= P3 by FUNCT_4:25;
A5: while>0(a,I) c= PW by FUNCT_4:25;
Initialize((intloc 0).-->1) c= sI by SCMFSA_M:13;
then
A6: PW halts_on sI by A2,A5;
set mW=LifeSpan(PW,sI);
A7: Initialize((intloc 0).-->1) c= s3 by SCMFSA_M:13;
then
A8: P3 halts_on s3 by A2,A4;
A9: DataPart Comput(PW, Comput(PW,sI,m1+2),m3+mW) = DataPart
Comput(P3,s3,m3)
proof
reconsider Wg=while>0(a,I)
as good InitHalting MacroInstruction of SCM+FSA by A2;
set Cm3=Comput(PW,sI,m1+2);
A10: I is_halting_onInit s,P by Th23;
A11: IC Cm3= 0 by A1,A10,Lm7;
A12: DataPart Cm3 = DataPart Comput(PI,sI,m1) by A1,A10,Lm7
.= DataPart Comput(PI,sI,m1);
A13: now
let f be FinSeq-Location;
A14: dom Initialize ((intloc 0) .--> 1) = {intloc 0,IC SCM+FSA}
by SCMFSA_M:11;
f <> intloc 0 & f <> IC SCM+FSA by SCMFSA_2:57,58;
then not f in dom Initialize((intloc 0).-->1) by A14,TARSKI:def 2;
hence s3.f = Comput(PI,sI,m1).f by FUNCT_4:11
.=Cm3.f by A12,SCMFSA_M:2;
end;
A15: Initialize((intloc 0).-->1) c= sI by SCMFSA_M:13;
A16: Cm3.intloc 0 =1 by A15,A5,Def2;
A17: now
let b be Int-Location;
per cases;
suppose
A18: b <> intloc 0;
A19: dom Initialize ((intloc 0) .--> 1) = {intloc 0,IC SCM+FSA}
by SCMFSA_M:11;
b <> IC SCM+FSA by SCMFSA_2:56;
then not b in dom Initialize((intloc 0).-->1) by A18,A19,TARSKI:def 2;
hence s3.b = Comput(PI,sI,m1).b by FUNCT_4:11
.=Cm3.b by A12,SCMFSA_M:2;
end;
suppose
b = intloc 0;
hence s3.b=Cm3.b by A16,SCMFSA_M:13,30;
end;
end;
Initialized Cm3 = Cm3 by A11,A16,SCMFSA_M:8;
then Initialize((intloc 0).-->1) c= Cm3 by SCMFSA_M:13;
then
A20: PW halts_on Cm3 by A2,A5;
IC Cm3=IC s3 by A11,MEMSTR_0:28,SCMFSA_M:13;
then
A21: Cm3 = s3 by A13,A17,SCMFSA_2:61;
then
A22: Result(PW,Cm3) = Result(P3,s3) by A2,A7,Lm5,A5,A4;
LifeSpan(PW,Cm3) = m3 by A2,A7,Lm5,A5,A4,A21;
hence
DataPart Comput(PW, Cm3,m3+mW)
= DataPart Comput(PW, Cm3,LifeSpan(PW,Cm3)) by A20,EXTPRO_1:25,NAT_1:11
.= DataPart Result(PW,Cm3) by A20,EXTPRO_1:23
.= DataPart Result(P3,s3) by A22
.= DataPart Comput(P3,s3,m3) by A8,EXTPRO_1:23;
end;
Initialize((intloc 0).-->1) c= sI by SCMFSA_M:13;
then
A23: P +* I halts_on sI by A3,Def1;
IExec(I,P,s) = Result(P +* I,Initialized s) by SCMFSA6B:def 1
.= Comput(PI,sI,m1) by A23,EXTPRO_1:23;
then
Result(PW,Initialized IExec(I,P,s)) = Result(P3,s3) by A2,A7,Lm5,A5,A4;
then
A24: Result(PW,Initialized IExec(I,P,s)) = Result(P3,s3);
A25: IExec(while>0(a,I),P,IExec(I,P,s))
= Result(PW,Initialized IExec(I,P,s)) by SCMFSA6B:def 1
.= Comput(P3,s3,m3) by A8,A24,EXTPRO_1:23;
A26: mW <= (m1+2+m3) + mW by NAT_1:11;
IExec(while>0(a,I),P,s) = Result(PW,Initialized s) by SCMFSA6B:def 1
.= Comput(PW,sI,mW) by A6,EXTPRO_1:23
.= Comput(PW,sI,m1+2+(m3+mW)) by A6,A26,EXTPRO_1:25;
then DataPart IExec(while>0(a,I),P,s)
= DataPart Comput(PW,sI,m1+2+(m3+mW))
.= DataPart Comput(P3,s3,m3) by A9,EXTPRO_1:4
.= DataPart IExec(while>0(a,I),P,IExec(I,P,s)) by A25;
hence
DataPart IExec(while>0(a,I),P,s) =
DataPart IExec(while>0(a,I),P,IExec(I,P,s));
end;
Lm9:
for I be good InitHalting really-closed MacroInstruction of SCM+FSA,
a be read-write
Int-Location st (for s be State of SCM+FSA,P holds (s.a > 0
implies IExec(I,P,s).a < s.a )) holds while>0(a,I) is InitHalting
proof
let I be good InitHalting really-closed MacroInstruction of SCM+FSA,
a be read-write Int-Location;
set D = Data-Locations SCM+FSA;
defpred P[Nat] means for t be State of SCM+FSA,Q
st t.a <= $1 holds
while>0(a,I) is_halting_onInit t,Q;
assume
A1: for s be State of SCM+FSA,P holds (s.a > 0 implies IExec(I,P,s).a < s.a);
A2: now
let k be Nat;
assume
A3: P[k];
now
let t be State of SCM+FSA,Q;
assume
A4: t.a <= k+1;
per cases;
suppose
t.a<>k+1;
then t.a < k+1 by A4,XXREAL_0:1;
hence while>0(a,I) is_halting_onInit t,Q by A3,INT_1:7;
end;
suppose
A5: t.a=k+1;
set l0=intloc 0;
set tW0= Initialized t, QW = Q +* while>0(a,I),
t1=Initialized t, Q1 = Q +* I,
Wt= Comput(QW, tW0,(LifeSpan(Q1,t1))+ 2), A = NAT,
It = Comput(Q1, t1,LifeSpan(Q1,t1));
A6: I is_halting_onInit t,Q by Th23;
then Q+*I halts_on Initialized t;
then
A7: Q1 halts_on t1;
A8: DataPart Wt = DataPart It by A5,A6,Lm7;
then
A9: Wt.l0 =It.l0 by SCMFSA_M:2
.=(Result(Q1,t1)).l0 by A7,EXTPRO_1:23
.=(Result(Q1,t1)).l0
.=IExec(I,Q,t).l0 by SCMFSA6B:def 1
.=1 by Th7;
Wt.a =It.a by A8,SCMFSA_M:2
.=(Result(Q1,t1)).a by A7,EXTPRO_1:23
.=(Result(Q1,t1)).a
.=IExec(I,Q,t).a by SCMFSA6B:def 1;
then Wt.a < k+1 by A1,A5;
then
while>0(a,I) is_halting_onInit Wt,QW by A3,INT_1:7;
then QW+*while>0(a,I) halts_on Initialized Wt;
then
A10: QW +* while>0(a,I) halts_on Initialized Wt;
IC Wt= 0 by A5,A6,Lm7;
then
A11: Initialized Wt = Wt by A9,SCMFSA_M:8;
now
consider m be Nat such that
A12: CurInstr(QW,Comput(QW,Wt,m)) = halt SCM+FSA by A11,A10;
take mm=((LifeSpan(Q1,t1))+ 2)+m;
thus CurInstr(QW,Comput(QW,tW0,mm))
= halt SCM+FSA by A12,EXTPRO_1:4;
end;
then QW halts_on tW0 by EXTPRO_1:29;
then Q+*while>0(a,I) halts_on Initialized t;
hence while>0(a,I) is_halting_onInit t,Q;
end;
end;
hence P[k+1];
end;
A13: P[ 0] by Lm6;
A14: for k be Nat holds P[k] from NAT_1:sch 2(A13,A2);
now
let t be State of SCM+FSA;
per cases;
suppose
t.a<=0;
hence while>0(a,I) is_halting_onInit t,Q by Lm6;
end;
suppose
t.a>0;
then reconsider n=t.a as Element of NAT by INT_1:3;
P[n] by A14;
hence while>0(a,I) is_halting_onInit t,Q;
end;
end;
hence thesis by Th23;
end;
:: end of copies of SCMISORT
Lm10:
for s being State of SCM+FSA,
I being good InitHalting really-closed Program
of SCM+FSA, a being read-write Int-Location st I does not destroy a
holds IExec(I ";" SubFrom(a,intloc 0),p,s).a = s.a - 1
proof
let s be State of SCM+FSA;
let I be good InitHalting really-closed Program of SCM+FSA;
let a be read-write Int-Location;
assume that
A1: I does not destroy a;
set I1 = I ";" SubFrom(a,intloc 0);
set ss = IExec(I1,p,s);
set s0 = Initialized s;
thus ss.a = Exec(SubFrom(a,intloc 0),IExec(I,p,s)).a by Th21
.= IExec(I,p,s).a - IExec(I,p,s).intloc 0 by SCMFSA_2:65
.= IExec(I,p,s).a - 1 by Th7
.= s0.a - 1 by A1,Th44
.= s.a - 1 by SCMFSA_M:37;
end;
theorem Th48:
for s being State of SCM+FSA,
I being good InitHalting really-closed MacroInstruction
of SCM+FSA, a being read-write Int-Location st I does not destroy a
holds IExec(I ";" SubFrom(a,intloc 0),p,s).a = s.a - 1 &
(s.a > 0 implies DataPart IExec(Times(a,I),p,s)
= DataPart IExec(Times(a,I),p,IExec(I ";" SubFrom(a,intloc 0),p,s)))
proof
let s be State of SCM+FSA;
let I be good InitHalting really-closed MacroInstruction of SCM+FSA;
let a be read-write Int-Location;
assume that
A1: I does not destroy a;
set I1 = I ";" SubFrom(a,intloc 0);
set ss = IExec(I1,p,s);
set s0 = Initialized s;
thus IExec(I ";" SubFrom(a,intloc 0),p,s).a = s.a - 1 by A1,Lm10;
assume
A2: s.a > 0;
reconsider II = I ";" SubFrom(a,intloc 0)
as good InitHalting really-closed MacroInstruction of SCM+FSA;
for s be State of SCM+FSA,P st s.a > 0 holds IExec(II,P,s).a < s.a
proof let s be State of SCM+FSA,P;
assume s.a > 0;
IExec(I ";" SubFrom(a,intloc 0),P,s).a = s.a - 1 by A1,Lm10;
hence IExec(II,P,s).a < s.a by
XREAL_1:44;
end;
then Times(a,I) is InitHalting by Lm9;
then DataPart IExec(while>0(a,II),p,s) =
DataPart IExec(while>0(a,II),p,IExec(II,p,s)) by A2,Lm8;
hence DataPart IExec(Times(a,I),p,s)
= DataPart IExec(Times(a,I),p,IExec(I ";" SubFrom(a,intloc 0),p,s));
end;
theorem
for s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA,
f be FinSeq-Location,a be read-write Int-Location st s.a <= 0
holds IExec(Times(a,I),p,s).f=s.f
proof
set D= Data-Locations SCM+FSA;
let s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA,
f be FinSeq-Location,a be read-write Int-Location;
assume
A1: s.a <= 0;
set s0 = Initialized s,
p0 = p;
A2: s0.a=s.a & s0.(intloc 0)=1 by SCMFSA_M:9,37;
f in FinSeq-Locations by SCMFSA_2:def 5;
then
A3: f in D by SCMFSA_2:100,XBOOLE_0:def 3;
DataPart IExec(Times(a,I),p,s) = DataPart IExec(Times(a,I),p0,s0)
by SCMFSA8C:3
.= DataPart s0 by A1,A2,Th47;
hence IExec(Times(a,I),p,s).f= (DataPart s0).f by A3,FUNCT_1:49
.= s0.f by A3,FUNCT_1:49
.= s.f by SCMFSA_M:37;
end;
theorem
for s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA,
b be Int-Location,a be read-write Int-Location st s.a <= 0
holds IExec(Times(a,I),p,s).b=(Initialized s).b
proof
set D= Data-Locations SCM+FSA;
let s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA,
b be Int-Location,a be read-write Int-Location;
assume
A1: s.a <= 0;
set s0 = Initialized s,
p0 = p;
A2: s0.a=s.a & s0.(intloc 0)=1 by SCMFSA_M:9,37;
b in Int-Locations by AMI_2:def 16;
then
A3: b in D by SCMFSA_2:100,XBOOLE_0:def 3;
DataPart IExec(Times(a,I),p,s) = DataPart IExec(Times(a,I),p0,s0)
by SCMFSA8C:3
.= DataPart s0 by A1,A2,Th47;
hence IExec(Times(a,I),p,s).b= (DataPart s0).b by A3,FUNCT_1:49
.= s0.b by A3,FUNCT_1:49;
end;
theorem
for s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA,
f be FinSeq-Location,a be read-write Int-Location
st I does not destroy a & s.a > 0
holds IExec(Times(a,I),p,s).f
=IExec(Times(a,I),p,IExec(I ";" SubFrom(a,intloc 0),p,s)).f
proof
set D= Data-Locations SCM+FSA;
let s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA, f be
FinSeq-Location,a be read-write Int-Location;
assume
A1: I does not destroy a & s.a > 0;
set IT=IExec(Times(a,I),p,IExec(I ";" SubFrom(a,intloc 0),p,s));
f in FinSeq-Locations by SCMFSA_2:def 5;
then
A2: f in D by SCMFSA_2:100,XBOOLE_0:def 3;
hence IExec(Times(a,I),p,s).f=(DataPart IExec(Times(a,I),p,s)).f
by FUNCT_1:49
.=(DataPart IT).f by A1,Th48
.= IT.f by A2,FUNCT_1:49;
end;
theorem
for s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA, b
be Int-Location,a be read-write Int-Location st I does not destroy a & s.a > 0
holds IExec(Times(a,I),p,s).b
=IExec(Times(a,I),p,IExec(I ";" SubFrom(a,intloc 0),p,s)).b
proof
set D= Data-Locations SCM+FSA;
let s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of SCM+FSA, b be
Int-Location,a be read-write Int-Location;
assume
A1: I does not destroy a & s.a > 0;
set IT=IExec(Times(a,I),p,IExec(I ";" SubFrom(a,intloc 0),p,s));
b in Int-Locations by AMI_2:def 16;
then
A2: b in D by SCMFSA_2:100,XBOOLE_0:def 3;
hence IExec(Times(a,I),p,s).b=(DataPart IExec(Times(a,I),p,s)).b
by FUNCT_1:49
.=(DataPart IT).b by A1,Th48
.= IT.b by A2,FUNCT_1:49;
end;
definition
let i be Instruction of SCM+FSA;
redefine attr i is good means
i does not destroy intloc 0;
compatibility
proof
rng Macro i = {i,halt SCM+FSA} by COMPOS_1:67;
then i in rng Macro i by TARSKI:def 2;
then
A1: Macro i does not destroy intloc 0 implies i does not destroy intloc 0;
A2: i does not destroy intloc 0 implies Macro i does not destroy intloc 0
by SCMFSA8C:48;
Macro i is good iff i is good by SFMASTR1:def 1;
hence i is good iff i does not destroy intloc 0 by A2,A1;
end;
end;
theorem
for s be State of SCM+FSA,I be InitHalting really-closed Program of SCM+FSA
st Initialize ((intloc 0) .--> 1) c= s & I c= P1 & I c= P2
for k be Nat
holds Comput(P1, s,k) = Comput(P2, s,k) &
CurInstr(P1,Comput(P1,s,k)) = CurInstr(P2,Comput(P2,s,k)) by Lm4;
theorem
for s be State of SCM+FSA,I be InitHalting really-closed Program of SCM+FSA
st Initialize ((intloc 0) .--> 1) c= s &
I c= P1 & I c= P2
holds LifeSpan(P1,s) = LifeSpan(P2,s) &
Result(P1,s) = Result(P2,s) by Lm5;
theorem
for s being State of SCM+FSA,
I being really-closed MacroInstruction of SCM+FSA,
a being read-write Int-Location st s.a <= 0
holds while>0(a,I) is_halting_onInit s,P by Lm6;
theorem
for s being State of SCM+FSA,
I be really-closed MacroInstruction of SCM+FSA,
a be read-write Int-Location st
I is_halting_onInit s,P & s.a >
0 holds IC Comput(P +* while>0(a,I), Initialized s,
LifeSpan(P +* I,Initialized s) + 2) = 0 &
DataPart Comput(P +* while>0(a,I), Initialized s,
LifeSpan(P +* I,Initialized s) + 2)
= DataPart Comput(P +* I, Initialized s,LifeSpan(P +* I,Initialized s))
by Lm7;
theorem
for s be State of SCM+FSA,
I be good InitHalting really-closed MacroInstruction of
SCM+FSA, a be read-write Int-Location st s.a > 0 & while>0(a,I) is InitHalting
holds DataPart IExec(while>0(a,I),P,s) =
DataPart IExec(while>0(a,I),P,IExec(I,P,s)) by Lm8;
theorem
for I be good InitHalting really-closed MacroInstruction of SCM+FSA,
a be read-write
Int-Location st (for s be State of SCM+FSA,P holds (s.a > 0
implies IExec(I,P,s).a < s.a )) holds while>0(a,I) is InitHalting by Lm9;