:: SCMISORT semantic presentation

REAL is non empty V5() V51() V53() set
NAT is non empty V5() epsilon-transitive epsilon-connected ordinal V51() V53() countable denumerable Element of K32(REAL)
K32(REAL) is cup-closed diff-closed preBoolean set
SCM+FSA is non empty with_non-empty_values IC-Ins-separated strict V108(3) with_explicit_jumps IC-relocable V157(3) AMI-Struct over 3
3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
K571() is set
K589(NAT,K571()) is Element of K571()
K564() is non empty set
K574() is Relation-like K571() -defined 3 -valued Function-like total V18(K571(),3) Element of K32(K33(K571(),3))
K33(K571(),3) is Relation-like set
K32(K33(K571(),3)) is cup-closed diff-closed preBoolean set
K575() is non empty Relation-like 3 -defined Function-like total set
K582() is non empty Relation-like K564() -defined K99((product (K574() (#) K575())),(product (K574() (#) K575()))) -valued Function-like total V18(K564(),K99((product (K574() (#) K575())),(product (K574() (#) K575())))) Function-yielding V151() Element of K32(K33(K564(),K99((product (K574() (#) K575())),(product (K574() (#) K575())))))
K574() (#) K575() is Relation-like K571() -defined Function-like total set
product (K574() (#) K575()) is functional with_common_domain product-like set
K99((product (K574() (#) K575())),(product (K574() (#) K575()))) is non empty functional set
K33(K564(),K99((product (K574() (#) K575())),(product (K574() (#) K575())))) is Relation-like set
K32(K33(K564(),K99((product (K574() (#) K575())),(product (K574() (#) K575()))))) is cup-closed diff-closed preBoolean set
AMI-Struct(# K571(),K589(NAT,K571()),K564(),K574(),K575(),K582() #) is strict AMI-Struct over 3
the carrier of SCM+FSA is non empty set
RAT is non empty V5() V51() V53() set
COMPLEX is non empty V5() V51() V53() set
NAT is non empty V5() epsilon-transitive epsilon-connected ordinal V51() V53() countable denumerable set
K32(NAT) is cup-closed diff-closed preBoolean set
K32(NAT) is cup-closed diff-closed preBoolean set
9 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Segm 9 is countable Element of K32(NAT)
Int-Locations is non empty set
K350() is set
K32(K350()) is cup-closed diff-closed preBoolean set
2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
K33(K350(),2) is Relation-like set
K32(K33(K350(),2)) is cup-closed diff-closed preBoolean set
K352() is Relation-like K350() -defined 2 -valued Function-like total V18(K350(),2) Element of K32(K33(K350(),2))
K353() is non empty Relation-like 2 -defined Function-like total set
K352() (#) K353() is Relation-like K350() -defined Function-like total set
product (K352() (#) K353()) is functional with_common_domain product-like set
K344() is non empty set
K99((product (K352() (#) K353())),(product (K352() (#) K353()))) is non empty functional set
K33(K344(),K99((product (K352() (#) K353())),(product (K352() (#) K353())))) is Relation-like set
K32(K33(K344(),K99((product (K352() (#) K353())),(product (K352() (#) K353()))))) is cup-closed diff-closed preBoolean set
K32( the carrier of SCM+FSA) is cup-closed diff-closed preBoolean set
the InstructionsF of SCM+FSA is non empty Relation-like standard-ins V97() J/A-independent V100() set
INT is non empty V5() V51() V53() set
the_Values_of SCM+FSA is non empty Relation-like non-empty non empty-yielding the carrier of SCM+FSA -defined Function-like total set
the Object-Kind of SCM+FSA is non empty Relation-like the carrier of SCM+FSA -defined 3 -valued Function-like total V18( the carrier of SCM+FSA,3) Element of K32(K33( the carrier of SCM+FSA,3))
K33( the carrier of SCM+FSA,3) is Relation-like set
K32(K33( the carrier of SCM+FSA,3)) is cup-closed diff-closed preBoolean set
the ValuesF of SCM+FSA is non empty Relation-like 3 -defined Function-like total set
the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA is non empty Relation-like the carrier of SCM+FSA -defined Function-like total set
Int-Locations is non empty Element of K32( the carrier of SCM+FSA)
K32(Int-Locations) is cup-closed diff-closed preBoolean set
K33(NAT,K32(NAT)) is Relation-like set
K32(K33(NAT,K32(NAT))) is cup-closed diff-closed preBoolean set
FinPartSt SCM+FSA is non empty functional Element of K32((sproduct (the_Values_of SCM+FSA)))
sproduct (the_Values_of SCM+FSA) is non empty functional set
K32((sproduct (the_Values_of SCM+FSA))) is cup-closed diff-closed preBoolean set
{ b₁ where b₁ is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible Element of sproduct (the_Values_of SCM+FSA) : b₁ is V53() } is set
K33((FinPartSt SCM+FSA),(FinPartSt SCM+FSA)) is Relation-like set
K32(K33((FinPartSt SCM+FSA),(FinPartSt SCM+FSA))) is cup-closed diff-closed preBoolean set
product (the_Values_of SCM+FSA) is non empty functional with_common_domain product-like set
K33(NAT,(product (the_Values_of SCM+FSA))) is Relation-like set
K32(K33(NAT,(product (the_Values_of SCM+FSA)))) is cup-closed diff-closed preBoolean set
K563() is set
K32(K571()) is cup-closed diff-closed preBoolean set
Fin Int-Locations is non empty cup-closed diff-closed preBoolean set
FinSeq-Locations is non empty V5() V51() V53() Element of K32( the carrier of SCM+FSA)
K573() is Element of K32(K571())
Fin FinSeq-Locations is non empty cup-closed diff-closed preBoolean set
K32(FinSeq-Locations) is cup-closed diff-closed preBoolean set
{} is empty Relation-like non-empty empty-yielding NAT -defined RAT -valued Function-like one-to-one constant functional ext-real non positive non negative epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V36() V37() V38() V39() V40() V41() integer V53() V54() V57() Cardinal-yielding countable FinSequence-like FinSubsequence-like FinSequence-membered Function-yielding V151() set
1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
0 is empty Relation-like non-empty empty-yielding NAT -defined RAT -valued Function-like one-to-one constant functional ext-real non positive non negative epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V36() V37() V38() V39() V40() V41() integer V53() V54() V57() Cardinal-yielding countable FinSequence-like FinSubsequence-like FinSequence-membered Function-yielding V151() Element of NAT
K33( the InstructionsF of SCM+FSA,(Fin Int-Locations)) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,(Fin Int-Locations))) is cup-closed diff-closed preBoolean set
halt SCM+FSA is ins-loc-free V107(3, SCM+FSA ) parahalting keeping_0 with_explicit_jumps IC-relocable V156(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
halt the InstructionsF of SCM+FSA is ins-loc-free with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
K33( the InstructionsF of SCM+FSA,(Fin FinSeq-Locations)) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,(Fin FinSeq-Locations))) is cup-closed diff-closed preBoolean set
4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
10 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
5 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
7 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
8 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
11 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
IC is V74( SCM+FSA ) Element of the carrier of SCM+FSA
NonZero SCM+FSA is Element of K32( the carrier of SCM+FSA)
Int-Locations \/ FinSeq-Locations is non empty Element of K32( the carrier of SCM+FSA)
intloc 0 is V111() read-only Element of the carrier of SCM+FSA
goto 2 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
Stop SCM+FSA is non empty V5() Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like constant V53() countable V95() non halt-free V104( SCM+FSA ) V105( SCM+FSA ) InitClosed InitHalting keepInt0_1 good V159(3, SCM+FSA ) set
K303((halt SCM+FSA)) is set
K555((intloc 0),1) is V5() Relation-like the carrier of SCM+FSA -defined {(intloc 0)} -defined {(intloc 0)} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant the_Values_of SCM+FSA -compatible V38() V39() V40() V41() V42() V43() V44() non-increasing V53() countable data-only set
{(intloc 0)} is non empty V53() countable set
{(intloc 0)} --> 1 is non empty Relation-like non-empty non empty-yielding {(intloc 0)} -defined NAT -valued RAT -valued INT -valued {1} -valued Function-like constant total V18({(intloc 0)},{1}) V38() V39() V40() V41() V53() countable Element of K32(K33({(intloc 0)},{1}))
{1} is non empty V50() V51() V53() countable set
K33({(intloc 0)},{1}) is Relation-like V53() countable set
K32(K33({(intloc 0)},{1})) is cup-closed diff-closed preBoolean V53() V57() countable set
Initialize K555((intloc 0),1) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable 0 -started set
Start-At (0,SCM+FSA) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable 0 -started set
(IC ) .--> 0 is V5() Relation-like the carrier of SCM+FSA -defined {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V38() V39() V40() V41() V42() V43() V44() non-increasing V53() countable Function-yielding V151() set
{(IC )} is non empty V53() countable set
{(IC )} --> 0 is non empty Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant total V18({(IC )},{0}) V38() V39() V40() V41() V53() countable Function-yielding V151() Element of K32(K33({(IC )},{0}))
{0} is non empty functional V53() V57() with_common_domain countable set
K33({(IC )},{0}) is Relation-like V53() countable set
K32(K33({(IC )},{0})) is cup-closed diff-closed preBoolean V53() V57() countable set
K555((intloc 0),1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible V53() countable 0 -started set
12 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Goto 0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() halt-free V105( SCM+FSA ) good set
goto 0 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
goto 3 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
K81(NAT,0,1) is non empty V53() countable Element of K32(NAT)
K351() is non empty Element of K32(K350())
(intloc 0) .--> 1 is V5() Relation-like the carrier of SCM+FSA -defined {(intloc 0)} -defined {(intloc 0)} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant the_Values_of SCM+FSA -compatible V38() V39() V40() V41() V42() V43() V44() non-increasing V53() countable data-only set
Initialize ((intloc 0) .--> 1) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable 0 -started set
((intloc 0) .--> 1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible V53() countable 0 -started set
dom (Initialize ((intloc 0) .--> 1)) is V53() countable set
K81( the carrier of SCM+FSA,(intloc 0),(IC )) is non empty V53() countable Element of K32( the carrier of SCM+FSA)
Sorting-Function is Relation-like FinPartSt SCM+FSA -defined FinPartSt SCM+FSA -valued Function-like Function-yielding V151() Element of K32(K33((FinPartSt SCM+FSA),(FinPartSt SCM+FSA)))
dom Sorting-Function is set
fsloc 0 is FinSeq-Location
0 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
- (0 + 1) is ext-real non positive V36() V37() integer set
a0 is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
dom a0 is V53() countable V132() set
UsedIntLoc a0 is V53() countable Element of K32(Int-Locations)
a1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a0 . a1 is set
a2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedIntLoc a2 is V53() countable Element of Fin Int-Locations
a1 .--> a2 is V5() Relation-like NAT -defined {a1} -defined the InstructionsF of SCM+FSA -valued Function-like one-to-one constant V53() countable set
{a1} is non empty V53() countable set
{a1} --> a2 is non empty Relation-like {a1} -defined the InstructionsF of SCM+FSA -valued {a2} -valued Function-like constant total V18({a1},{a2}) V53() countable Element of K32(K33({a1},{a2}))
{a2} is non empty V53() countable set
K33({a1},{a2}) is Relation-like V53() countable set
K32(K33({a1},{a2})) is cup-closed diff-closed preBoolean V53() V57() countable set
a0 +* (a1 .--> a2) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
UsedIntLoc (a0 +* (a1 .--> a2)) is V53() countable Element of K32(Int-Locations)
a4 is non empty Relation-like the InstructionsF of SCM+FSA -defined Fin Int-Locations -valued Function-like total V18( the InstructionsF of SCM+FSA, Fin Int-Locations) Element of K32(K33( the InstructionsF of SCM+FSA,(Fin Int-Locations)))
a0 (#) a4 is Relation-like NAT -defined Fin Int-Locations -valued Function-like V53() countable set
Union (a0 (#) a4) is set
rng (a0 (#) a4) is V53() countable set
union (rng (a0 (#) a4)) is set
(a0 +* (a1 .--> a2)) (#) a4 is Relation-like NAT -defined Fin Int-Locations -valued Function-like V53() countable set
initializeWorkMem is non empty Relation-like the InstructionsF of SCM+FSA -defined Fin Int-Locations -valued Function-like total V18( the InstructionsF of SCM+FSA, Fin Int-Locations) Element of K32(K33( the InstructionsF of SCM+FSA,(Fin Int-Locations)))
(a0 +* (a1 .--> a2)) (#) initializeWorkMem is Relation-like NAT -defined Fin Int-Locations -valued Function-like V53() countable set
Union ((a0 +* (a1 .--> a2)) (#) initializeWorkMem) is set
rng ((a0 +* (a1 .--> a2)) (#) initializeWorkMem) is V53() countable set
union (rng ((a0 +* (a1 .--> a2)) (#) initializeWorkMem)) is set
f0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a4 . f0 is V53() countable Element of Fin Int-Locations
initializeWorkMem . f0 is V53() countable Element of Fin Int-Locations
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedIntLoc b1 is V53() countable Element of Fin Int-Locations
(a0 +* (a1 .--> a2)) . a1 is set
a0 +* (a1,a2) is Relation-like Function-like set
(a0 +* (a1,a2)) . a1 is set
dom a4 is non empty set
rng a0 is V53() countable set
dom (a0 (#) a4) is V53() countable V132() set
dom (a0 +* (a1 .--> a2)) is V53() countable V132() set
rng (a0 +* (a1 .--> a2)) is V53() countable set
dom ((a0 +* (a1 .--> a2)) (#) a4) is V53() countable V132() set
f0 is set
(a0 +* (a1 .--> a2)) . f0 is set
dom (a1 .--> a2) is V5() V53() countable V132() set
a0 . f0 is set
(a0 (#) a4) . f0 is set
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a4 . b1 is V53() countable Element of Fin Int-Locations
((a0 +* (a1 .--> a2)) (#) a4) . f0 is set
(a0 (#) a4) . f0 is set
a0 . f0 is set
a4 . (a0 . f0) is set
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedIntLoc b1 is V53() countable Element of Fin Int-Locations
a4 . b1 is V53() countable Element of Fin Int-Locations
((a0 +* (a1 .--> a2)) (#) a4) . f0 is set
b2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedIntLoc b2 is V53() countable Element of Fin Int-Locations
a0 is V111() Element of the carrier of SCM+FSA
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a1 ";" (Goto 0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
if>0 (a0,(a1 ";" (Goto 0)),(Stop SCM+FSA)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
card a1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card a1) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(if>0 (a0,(a1 ";" (Goto 0)),(Stop SCM+FSA))) . ((card a1) + 4) is set
goto ((card a1) + 4) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
card (Stop SCM+FSA) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (Stop SCM+FSA)) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a0 >0_goto ((card (Stop SCM+FSA)) + 3) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
card (a1 ";" (Goto 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (a1 ";" (Goto 0))) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Goto ((card (a1 ";" (Goto 0))) + 1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() halt-free V105( SCM+FSA ) good set
((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
(((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(Goto 0) ";" (Stop SCM+FSA) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free good set
(card a1) + 6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card (if>0 (a0,(a1 ";" (Goto 0)),(Stop SCM+FSA))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
dom (if>0 (a0,(a1 ";" (Goto 0)),(Stop SCM+FSA))) is non empty V53() countable V132() set
0 + ((card a1) + 4) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(Goto 0) . 0 is set
dom (Goto 0) is non empty V53() countable V132() set
((Goto 0) ";" (Stop SCM+FSA)) . 0 is set
Directed (Goto 0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() halt-free V105( SCM+FSA ) good set
(Directed (Goto 0)) . 0 is set
card ((Goto 0) ";" (Stop SCM+FSA)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (Goto 0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (Goto 0)) + (card (Stop SCM+FSA)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
1 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
dom ((Goto 0) ";" (Stop SCM+FSA)) is non empty V53() countable V132() set
{ (b₁ + ((card a1) + 4)) where b₁ is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT : b₁ in dom ((Goto 0) ";" (Stop SCM+FSA)) } is set
Shift (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
dom (Shift (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))) is non empty V53() countable V132() set
(Shift (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))) /. ((card a1) + 4) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(Shift (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))) . (0 + ((card a1) + 4)) is set
card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1)))) + (card a1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (Goto ((card (a1 ";" (Goto 0))) + 1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA))) + (card (Goto ((card (a1 ";" (Goto 0))) + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((card ((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA))) + (card (Goto ((card (a1 ";" (Goto 0))) + 1)))) + (card a1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA))) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((card ((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA))) + 1) + (card a1) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
2 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(2 + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((2 + 1) + 1) + (card a1) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
dom ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) is non empty V53() countable V132() set
Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable non halt-free set
IncAddr (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
Shift ((IncAddr (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))),((card a1) + 4)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
IncAddr ((Shift (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))),((card a1) + 4)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
stop ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
K293(((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1),(Stop SCM+FSA)) is Relation-like Function-like T-Sequence-like set
CutLastLoc (stop ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
(((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" (a1 ";" (Goto 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" (a1 ";" (Goto 0))) ";" (Stop SCM+FSA) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) ";" (Goto 0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) ";" (Goto 0)) ";" (Stop SCM+FSA) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) ";" ((Goto 0) ";" (Stop SCM+FSA)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Directed ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() halt-free V105( SCM+FSA ) set
(Directed ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)) +* (Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like V53() countable non halt-free set
dom (Directed ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)) is non empty V53() countable V132() set
dom (Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))) is V53() countable V132() set
(dom (Directed ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1))) \/ (dom (Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)))) is non empty V53() countable set
Directed (((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1),(card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() halt-free set
dom (Directed (((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1),(card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)))) is V53() countable V132() set
(dom (Directed (((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1),(card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1))))) \/ (dom (Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)))) is V53() countable set
goto (card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) +~ ((halt SCM+FSA),(goto (card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)))) is Relation-like Function-like set
dom (((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) +~ ((halt SCM+FSA),(goto (card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1))))) is set
(dom (((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1) +~ ((halt SCM+FSA),(goto (card ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)))))) \/ (dom (Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)))) is set
(dom ((((a0 >0_goto ((card (Stop SCM+FSA)) + 3)) ";" (Stop SCM+FSA)) ";" (Goto ((card (a1 ";" (Goto 0))) + 1))) ";" a1)) \/ (dom (Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4)))) is non empty V53() countable set
(Reloc (((Goto 0) ";" (Stop SCM+FSA)),((card a1) + 4))) . ((card a1) + 4) is set
IncAddr ((goto 0),((card a1) + 4)) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a0 is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
dom a0 is V53() countable V132() set
UsedInt*Loc a0 is V53() countable Element of K32(FinSeq-Locations)
a1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a0 . a1 is set
a2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedInt*Loc a2 is V53() countable Element of Fin FinSeq-Locations
a1 .--> a2 is V5() Relation-like NAT -defined {a1} -defined the InstructionsF of SCM+FSA -valued Function-like one-to-one constant V53() countable set
{a1} is non empty V53() countable set
{a1} --> a2 is non empty Relation-like {a1} -defined the InstructionsF of SCM+FSA -valued {a2} -valued Function-like constant total V18({a1},{a2}) V53() countable Element of K32(K33({a1},{a2}))
{a2} is non empty V53() countable set
K33({a1},{a2}) is Relation-like V53() countable set
K32(K33({a1},{a2})) is cup-closed diff-closed preBoolean V53() V57() countable set
a0 +* (a1 .--> a2) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
UsedInt*Loc (a0 +* (a1 .--> a2)) is V53() countable Element of K32(FinSeq-Locations)
a4 is non empty Relation-like the InstructionsF of SCM+FSA -defined Fin FinSeq-Locations -valued Function-like total V18( the InstructionsF of SCM+FSA, Fin FinSeq-Locations) Element of K32(K33( the InstructionsF of SCM+FSA,(Fin FinSeq-Locations)))
a0 (#) a4 is Relation-like NAT -defined Fin FinSeq-Locations -valued Function-like V53() countable set
Union (a0 (#) a4) is set
rng (a0 (#) a4) is V53() countable set
union (rng (a0 (#) a4)) is set
(a0 +* (a1 .--> a2)) (#) a4 is Relation-like NAT -defined Fin FinSeq-Locations -valued Function-like V53() countable set
initializeWorkMem is non empty Relation-like the InstructionsF of SCM+FSA -defined Fin FinSeq-Locations -valued Function-like total V18( the InstructionsF of SCM+FSA, Fin FinSeq-Locations) Element of K32(K33( the InstructionsF of SCM+FSA,(Fin FinSeq-Locations)))
(a0 +* (a1 .--> a2)) (#) initializeWorkMem is Relation-like NAT -defined Fin FinSeq-Locations -valued Function-like V53() countable set
Union ((a0 +* (a1 .--> a2)) (#) initializeWorkMem) is set
rng ((a0 +* (a1 .--> a2)) (#) initializeWorkMem) is V53() countable set
union (rng ((a0 +* (a1 .--> a2)) (#) initializeWorkMem)) is set
f0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a4 . f0 is V53() countable Element of Fin FinSeq-Locations
initializeWorkMem . f0 is V53() countable Element of Fin FinSeq-Locations
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedInt*Loc b1 is V53() countable Element of Fin FinSeq-Locations
(a0 +* (a1 .--> a2)) . a1 is set
a0 +* (a1,a2) is Relation-like Function-like set
(a0 +* (a1,a2)) . a1 is set
dom a4 is non empty set
rng a0 is V53() countable set
dom (a0 (#) a4) is V53() countable V132() set
dom (a0 +* (a1 .--> a2)) is V53() countable V132() set
rng (a0 +* (a1 .--> a2)) is V53() countable set
dom ((a0 +* (a1 .--> a2)) (#) a4) is V53() countable V132() set
f0 is set
(a0 +* (a1 .--> a2)) . f0 is set
dom (a1 .--> a2) is V5() V53() countable V132() set
a0 . f0 is set
(a0 (#) a4) . f0 is set
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a4 . b1 is V53() countable Element of Fin FinSeq-Locations
((a0 +* (a1 .--> a2)) (#) a4) . f0 is set
(a0 (#) a4) . f0 is set
a0 . f0 is set
a4 . (a0 . f0) is set
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedInt*Loc b1 is V53() countable Element of Fin FinSeq-Locations
a4 . b1 is V53() countable Element of Fin FinSeq-Locations
((a0 +* (a1 .--> a2)) (#) a4) . f0 is set
b2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
UsedInt*Loc b2 is V53() countable Element of Fin FinSeq-Locations
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a2 is V111() Element of the carrier of SCM+FSA
a1 is V111() Element of the carrier of SCM+FSA
while>0 (a1,a0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
card a0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card a0) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((card a0) + 4) .--> (goto 0) is V5() Relation-like NAT -defined {((card a0) + 4)} -defined the InstructionsF of SCM+FSA -valued Function-like one-to-one constant V53() countable set
{((card a0) + 4)} is non empty V50() V51() V53() countable set
{((card a0) + 4)} --> (goto 0) is non empty Relation-like {((card a0) + 4)} -defined the InstructionsF of SCM+FSA -valued {(goto 0)} -valued Function-like constant total V18({((card a0) + 4)},{(goto 0)}) V53() countable Element of K32(K33({((card a0) + 4)},{(goto 0)}))
{(goto 0)} is non empty V53() countable set
K33({((card a0) + 4)},{(goto 0)}) is Relation-like V53() countable set
K32(K33({((card a0) + 4)},{(goto 0)})) is cup-closed diff-closed preBoolean V53() V57() countable set
a0 ";" (Goto 0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
if>0 (a1,(a0 ";" (Goto 0)),(Stop SCM+FSA)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(if>0 (a1,(a0 ";" (Goto 0)),(Stop SCM+FSA))) +* (((card a0) + 4) .--> (goto 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Initialize (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
IExec (a2,a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a0 +* a2),(Initialize (Initialized a1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
initializeWorkMem is V111() Element of the carrier of SCM+FSA
(IExec (a2,a0,a1)) . initializeWorkMem is ext-real V36() V37() integer set
Result ((a0 +* a2),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Result ((a0 +* a2),(Initialize (Initialized a1)))) . initializeWorkMem is ext-real V36() V37() integer set
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) . initializeWorkMem is ext-real V36() V37() integer set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a2 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting set
a4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (a0,a2,a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (a0,a2,a4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a0,a2,a4)) . (IC ) is set
dom a3 is non empty V53() countable V132() set
Comput (a1,a2,a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (a1,a2,a4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a1,a2,a4)) . (IC ) is set
a5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (a1,a2,a5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (a1,a2,a5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a1,a2,a5)) . (IC ) is set
CurInstr (a1,(Comput (a1,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a1 /. (IC (Comput (a1,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a1 . (IC (Comput (a1,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a3 . (IC (Comput (a1,a2,a4))) is set
a0 . (IC (Comput (a0,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
CurInstr (a0,(Comput (a0,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a0 /. (IC (Comput (a0,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a2 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
LifeSpan (a0,a2) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
LifeSpan (a1,a2) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Result (a0,a2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Result (a1,a2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting set
a4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (a1,a2,a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr (a1,(Comput (a1,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput (a1,a2,a4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a1,a2,a4)) . (IC ) is set
a1 /. (IC (Comput (a1,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Comput (a0,a2,a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr (a0,(Comput (a0,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput (a0,a2,a4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a0,a2,a4)) . (IC ) is set
a0 /. (IC (Comput (a0,a2,a4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Comput (a1,a2,(LifeSpan (a0,a2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr (a1,(Comput (a1,a2,(LifeSpan (a0,a2))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput (a1,a2,(LifeSpan (a0,a2)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a1,a2,(LifeSpan (a0,a2)))) . (IC ) is set
a1 /. (IC (Comput (a1,a2,(LifeSpan (a0,a2))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Comput (a0,a2,(LifeSpan (a0,a2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr (a0,(Comput (a0,a2,(LifeSpan (a0,a2))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput (a0,a2,(LifeSpan (a0,a2)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (a0,a2,(LifeSpan (a0,a2)))) . (IC ) is set
a0 /. (IC (Comput (a0,a2,(LifeSpan (a0,a2))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a3 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a3 is ext-real V36() V37() integer set
while>0 (a3,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) . a3 is ext-real V36() V37() integer set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is V111() Element of the carrier of SCM+FSA
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
while>0 (a1,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a1,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a4 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan ((a0 +* a2),(Initialized a4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
1 + a5 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),(1 + a5)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),(1 + a5))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),(1 + a5))) . (IC ) is set
Comput ((a0 +* a2),(Initialized a4),a5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialized a4),a5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialized a4),a5)) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialized a4),a5))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
DataPart (Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),(1 + a5))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),(1 + a5))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialized a4),a5)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialized a4),a5)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(1 + a5) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),((1 + a5) + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),((1 + a5) + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),((1 + a5) + 1))) . (IC ) is set
a5 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* a2),(Initialized a4),(a5 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialized a4),(a5 + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialized a4),(a5 + 1))) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialized a4),(a5 + 1)))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
DataPart (Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),((1 + a5) + 1))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a1,a2))),(Initialized a4),((1 + a5) + 1))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialized a4),(a5 + 1))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialized a4),(a5 + 1))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Initialize (Initialized a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a4) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is V111() Element of the carrier of SCM+FSA
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 (a1,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a1,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
card a2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card a2) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
goto ((card a2) + 4) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a3 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan ((a0 +* a2),(Initialized a3)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
1 + (LifeSpan ((a0 +* a2),(Initialized a3))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a1,a2))),(Initialized a3),(1 + (LifeSpan ((a0 +* a2),(Initialized a3))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a1,a2))),(Initialized a3),(1 + (LifeSpan ((a0 +* a2),(Initialized a3)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a1,a2))),(Initialized a3),(1 + (LifeSpan ((a0 +* a2),(Initialized a3)))))) . (IC ) is set
Comput ((a0 +* a2),(Initialized a3),(LifeSpan ((a0 +* a2),(Initialized a3)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialized a3),(LifeSpan ((a0 +* a2),(Initialized a3))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialized a3),(LifeSpan ((a0 +* a2),(Initialized a3))))) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialized a3),(LifeSpan ((a0 +* a2),(Initialized a3)))))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
CurInstr ((a0 +* (while>0 (a1,a2))),(Comput ((a0 +* (while>0 (a1,a2))),(Initialized a3),(1 + (LifeSpan ((a0 +* a2),(Initialized a3))))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a1,a2))) /. (IC (Comput ((a0 +* (while>0 (a1,a2))),(Initialized a3),(1 + (LifeSpan ((a0 +* a2),(Initialized a3))))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Initialize (Initialized a3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a3) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a0 +* a2),(Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a0 +* a2),(Initialized a1))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a3 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a3 is ext-real V36() V37() integer set
while>0 (a3,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a3,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . (IC ) is set
dom (while>0 (a3,a2)) is non empty V53() countable V132() set
Initialize (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) . a3 is ext-real V36() V37() integer set
b1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),b1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),b1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),b1)) . (IC ) is set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a0 +* a2),(Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a0 +* a2),(Initialized a1))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a3 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a3 is ext-real V36() V37() integer set
while>0 (a3,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a3,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
dom (while>0 (a3,a2)) is non empty V53() countable V132() set
Initialize (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
dom a2 is non empty V53() countable V132() set
a6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* a2),(Initialize (Initialized a1)),a6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),a6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),a6)) . (IC ) is set
(Initialized a1) . a3 is ext-real V36() V37() integer set
a6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),a6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),a6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),a6)) . (IC ) is set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a0 +* a2),(Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a0 +* a2),(Initialized a1))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
a3 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a3 is ext-real V36() V37() integer set
while>0 (a3,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a3,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . (IC ) is set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Initialize (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 >0_goto 4 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
LifeSpan ((a0 +* a2),(Initialize (Initialized a1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card a2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card a2) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
dom (while>0 (a3,a2)) is non empty V53() countable V132() set
dom a2 is non empty V53() countable V132() set
b5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* a2),(Initialize (Initialized a1)),b5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),b5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),b5)) . (IC ) is set
b5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
1 + b5 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + b5)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + b5))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + b5))) . (IC ) is set
Comput ((a0 +* a2),(Initialize (Initialized a1)),b5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),b5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),b5)) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),b5))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + b5))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + b5))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialize (Initialized a1)),b5)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialize (Initialized a1)),b5)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
b5 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b5 + 0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(1 + b5) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + b5) + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + b5) + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + b5) + 1))) . (IC ) is set
Comput ((a0 +* a2),(Initialize (Initialized a1)),(b5 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),(b5 + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(b5 + 1))) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),(b5 + 1)))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + b5) + 1))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + b5) + 1))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialize (Initialized a1)),(b5 + 1))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(b5 + 1))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
1 + (b5 + 1) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (b5 + 1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (b5 + 1)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (b5 + 1)))) . (IC ) is set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (b5 + 1)))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (b5 + 1)))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(a0 +* (while>0 (a3,a2))) . 0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . 0 is set
dom (Start-At (0,SCM+FSA)) is non empty V53() countable set
IC (Initialize (Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Initialize (Initialized a1)) . (IC ) is set
IC (Start-At (0,SCM+FSA)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Start-At (0,SCM+FSA)) . (IC ) is set
0 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(0 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)) is set
Following ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) /. (IC (Initialize (Initialized a1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)))),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))))) . (Initialize (Initialized a1)) is set
Exec ((a3 >0_goto 4),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (a3 >0_goto 4) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (a3 >0_goto 4)) . (Initialize (Initialized a1)) is set
b5 is FinSeq-Location
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) . b5 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Initialize (Initialized a1)) . b5 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
b5 is V111() Element of the carrier of SCM+FSA
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) . b5 is ext-real V36() V37() integer set
(Initialize (Initialized a1)) . b5 is ext-real V36() V37() integer set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Initialize (Initialized a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Initialize (Initialized a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1) + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Initialize (Initialized a1)) . a3 is ext-real V36() V37() integer set
(Initialized a1) . a3 is ext-real V36() V37() integer set
1 + 0 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + 0)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + 0))) . (IC ) is set
Comput ((a0 +* a2),(Initialize (Initialized a1)),0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),0)) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),0))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + 0))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + 0))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialize (Initialized a1)),0)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialize (Initialized a1)),0)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) . (IC ) is set
Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) . (IC ) is set
(IC (Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) is set
goto ((card a2) + 4) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
Exec ((goto ((card a2) + 4)),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto ((card a2) + 4)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto ((card a2) + 4))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) is set
i1 is FinSeq-Location
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(a0 +* (while>0 (a3,a2))) . ((card a2) + 4) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . ((card a2) + 4) is set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) . (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) is set
Exec ((goto 0),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 0) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 0)) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) is set
i1 is FinSeq-Location
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1) + 1))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
i1 is V111() Element of the carrier of SCM+FSA
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) . i1 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))))) . i1 is ext-real V36() V37() integer set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
i1 is V111() Element of the carrier of SCM+FSA
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1) + 1))) . i1 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),((1 + (LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) + 1))) . i1 is ext-real V36() V37() integer set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a0 +* a2),(Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a0 +* a2),(Initialized a1))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
IExec (a2,a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a4 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a4 is ext-real V36() V37() integer set
while>0 (a4,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a4,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialize (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
b2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2)) . (IC ) is set
Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
LifeSpan ((a0 +* a2),(Initialize (Initialized a1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
b5 is V111() Element of the carrier of SCM+FSA
(Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2)) . b5 is ext-real V36() V37() integer set
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) . b5 is ext-real V36() V37() integer set
(IExec (a2,a0,a1)) . b5 is ext-real V36() V37() integer set
b5 is FinSeq-Location
(Comput ((a0 +* (while>0 (a4,a2))),(Initialized a1),b2)) . b5 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* a2),(Initialize (Initialized a1)),(LifeSpan ((a0 +* a2),(Initialize (Initialized a1)))))) . b5 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (a2,a0,a1)) . b5 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
a3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a2 is V111() non read-only Element of the carrier of SCM+FSA
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 (a2,a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a3 +* (while>0 (a2,a1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
(a3 +* (while>0 (a2,a1))) +* a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
a5 . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
a6 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a5 . (a6 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . a6 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Initialized (a5 . a6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(a5 . a6) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . a6))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . a6)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a3 +* (while>0 (a2,a1))),(Initialized (a5 . a6)),((LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . a6)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
down H₁(a6,a5 . a6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a4 is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
a4 . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
a5 . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a6 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
initializeWorkMem is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
initializeWorkMem + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a4 . (initializeWorkMem + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a4 . initializeWorkMem is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Initialized (a4 . initializeWorkMem) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(a4 . initializeWorkMem) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a4 . initializeWorkMem))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a4 . initializeWorkMem)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a3 +* (while>0 (a2,a1))),(Initialized (a4 . initializeWorkMem)),((LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a4 . initializeWorkMem)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
down (Comput ((a3 +* (while>0 (a2,a1))),(Initialized (a4 . initializeWorkMem)),((LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a4 . initializeWorkMem)))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
initializeWorkMem is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
initializeWorkMem + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a5 . (initializeWorkMem + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . initializeWorkMem is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Initialized (a5 . initializeWorkMem) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(a5 . initializeWorkMem) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . initializeWorkMem))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . initializeWorkMem)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a3 +* (while>0 (a2,a1))),(Initialized (a5 . initializeWorkMem)),((LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . initializeWorkMem)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
down (Comput ((a3 +* (while>0 (a2,a1))),(Initialized (a5 . initializeWorkMem)),((LifeSpan (((a3 +* (while>0 (a2,a1))) +* a1),(Initialized (a5 . initializeWorkMem)))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a2 is V111() non read-only Element of the carrier of SCM+FSA
a3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a4 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
(a0,a1,a2,a4) is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
(a0,a1,a2,a4) . (a3 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(a0,a1,a2,a4) . a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(((a0,a1,a2,a4) . a3),a1,a2,a4) is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
(((a0,a1,a2,a4) . a3),a1,a2,a4) . 1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(((a0,a1,a2,a4) . a3),a1,a2,a4) . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
while>0 (a2,a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a4 +* (while>0 (a2,a1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialized ((((a0,a1,a2,a4) . a3),a1,a2,a4) . 0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((((a0,a1,a2,a4) . a3),a1,a2,a4) . 0) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(a4 +* (while>0 (a2,a1))) +* a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan (((a4 +* (while>0 (a2,a1))) +* a1),(Initialized ((((a0,a1,a2,a4) . a3),a1,a2,a4) . 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a4 +* (while>0 (a2,a1))) +* a1),(Initialized ((((a0,a1,a2,a4) . a3),a1,a2,a4) . 0)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a4 +* (while>0 (a2,a1))),(Initialized ((((a0,a1,a2,a4) . a3),a1,a2,a4) . 0)),((LifeSpan (((a4 +* (while>0 (a2,a1))) +* a1),(Initialized ((((a0,a1,a2,a4) . a3),a1,a2,a4) . 0)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
0 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(((a0,a1,a2,a4) . a3),a1,a2,a4) . (0 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
0 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a2 is V111() non read-only Element of the carrier of SCM+FSA
while>0 (a2,a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a2,a1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
(a0 +* (while>0 (a2,a1))) +* a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(a3,a1,a2,a0) is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
(a3,a1,a2,a0) . (0 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Initialized a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a3 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(a3,a1,a2,a0) . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Initialized ((a3,a1,a2,a0) . 0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . 0) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . 0)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized ((a3,a1,a2,a0) . 0)),((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . 0)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a2 is V111() non read-only Element of the carrier of SCM+FSA
while>0 (a2,a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a2,a1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
(a0 +* (while>0 (a2,a1))) +* a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(a3,a1,a2,a0) is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
Initialized a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a3 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
IC ((a3,a1,a2,a0) . a4) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . a4) . (IC ) is set
a5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),a5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
((a3,a1,a2,a0) . a4) . (intloc 0) is ext-real V36() V37() integer set
Initialized ((a3,a1,a2,a0) . a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . a4) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a4 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(a3,a1,a2,a0) . (a4 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . a4))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . a4)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a5 + ((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . a4)))) + 3) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),(a5 + ((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . a4)))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialize (Initialized ((a3,a1,a2,a0) . a4)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized ((a3,a1,a2,a0) . a4)) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Comput ((a0 +* (while>0 (a2,a1))),((a3,a1,a2,a0) . a4),((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . a4)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
K33((product (the_Values_of SCM+FSA)),NAT) is Relation-like set
K32(K33((product (the_Values_of SCM+FSA)),NAT)) is cup-closed diff-closed preBoolean set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a2 is V111() non read-only Element of the carrier of SCM+FSA
while>0 (a2,a1) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a0 +* (while>0 (a2,a1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(a3,a1,a2,a0) is non empty Relation-like NAT -defined product (the_Values_of SCM+FSA) -valued Function-like total V18( NAT , product (the_Values_of SCM+FSA)) Function-yielding V151() Element of K32(K33(NAT,(product (the_Values_of SCM+FSA))))
a5 is non empty Relation-like product (the_Values_of SCM+FSA) -defined NAT -valued Function-like total V18( product (the_Values_of SCM+FSA), NAT ) V38() V39() V40() V41() Element of K32(K33((product (the_Values_of SCM+FSA)),NAT))
Initialized a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a3 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(a0 +* (while>0 (a2,a1))) +* (while>0 (a2,a1)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
f0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
(a3,a1,a2,a0) . f0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . ((a3,a1,a2,a0) . f0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
f0 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(a3,a1,a2,a0) . (f0 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . ((a3,a1,a2,a0) . (f0 + 1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
f0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
(a3,a1,a2,a0) . f0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . ((a3,a1,a2,a0) . f0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
b1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . (0 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(a0 +* (while>0 (a2,a1))) +* a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),b2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
b2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . b2 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . ((a3,a1,a2,a0) . b2) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
b2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
b2 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(a3,a1,a2,a0) . (b2 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(a3,a1,a2,a0) . b2 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(b2 + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(b2 + 1) + 0 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),b5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
b5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),b5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
((a3,a1,a2,a0) . (b2 + 1)) . (intloc 0) is ext-real V36() V37() integer set
1 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b2 + (1 + 1) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b2 + 0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a5 . ((a3,a1,a2,a0) . b2) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . b2) . a2 is ext-real V36() V37() integer set
(a0 +* (while>0 (a2,a1))) +* a1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialized ((a3,a1,a2,a0) . (b2 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . (b2 + 1)) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . (b2 + 1)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . (b2 + 1))))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b5 + ((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . (b2 + 1))))) + 3) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Initialized ((a3,a1,a2,a0) . b2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . b2) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . b2))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . b2)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized ((a3,a1,a2,a0) . b2)),((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . b2)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC ((a3,a1,a2,a0) . (b2 + 1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . (b2 + 1)) . (IC ) is set
(a3,a1,a2,a0) . ((b2 + 1) + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),(b5 + ((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . (b2 + 1))))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
b6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),b6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
b3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),b3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(a3,a1,a2,a0) . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
((a3,a1,a2,a0) . 0) . a2 is ext-real V36() V37() integer set
a3 . a2 is ext-real V36() V37() integer set
b2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
b2 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . b3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
(a3,a1,a2,a0) . b1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
Initialized ((a3,a1,a2,a0) . b1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . b1) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Initialize ((a3,a1,a2,a0) . b1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . b1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a5 . ((a3,a1,a2,a0) . b3) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . b3) . a2 is ext-real V36() V37() integer set
Initialized ((a3,a1,a2,a0) . b3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . b3) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . b3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . b3)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized ((a3,a1,a2,a0) . b3)),((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . b3)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC ((a3,a1,a2,a0) . b1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . b1) . (IC ) is set
b3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(a3,a1,a2,a0) . (b3 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
((a3,a1,a2,a0) . (b3 + 1)) . (intloc 0) is ext-real V36() V37() integer set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized a3))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
i3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
((a3,a1,a2,a0) . b1) . a2 is ext-real V36() V37() integer set
i4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),((a3,a1,a2,a0) . b1),i4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a2,a1))),(Comput ((a0 +* (while>0 (a2,a1))),((a3,a1,a2,a0) . b1),i4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a0 +* (while>0 (a2,a1))),((a3,a1,a2,a0) . b1),i4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a2,a1))),((a3,a1,a2,a0) . b1),i4)) . (IC ) is set
(a0 +* (while>0 (a2,a1))) /. (IC (Comput ((a0 +* (while>0 (a2,a1))),((a3,a1,a2,a0) . b1),i4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
i4 + i3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),(i4 + i3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a2,a1))),(Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i3)),i4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
i5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . 0 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
a5 . ((a3,a1,a2,a0) . 0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a3 . a2 is ext-real V36() V37() integer set
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) . (IC ) is set
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
i5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . 1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
i6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
i6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
(a3,a1,a2,a0) . i6 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
body3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),body3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
b1 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
i6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
i6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
(a3,a1,a2,a0) . i6 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
body3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
w2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),w2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),w2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
w2 + w3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized ((a3,a1,a2,a0) . b1)),w4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) . (IC ) is set
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
body3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . body3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
w3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),w3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),w3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
w3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
w4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
w4 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((a3,a1,a2,a0) . body3) . (intloc 0) is ext-real V36() V37() integer set
a5 . ((a3,a1,a2,a0) . body3) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . body3) . a2 is ext-real V36() V37() integer set
w5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),w5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),w5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized ((a3,a1,a2,a0) . body3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . body3) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . body3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . body3)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
w5 + ((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . body3)))) + 3) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
T3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer set
w5 + T3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(a3,a1,a2,a0) . w4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
w4 + 0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
m1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),m1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a5 . ((a3,a1,a2,a0) . w4) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . w4) . a2 is ext-real V36() V37() integer set
Initialized ((a3,a1,a2,a0) . w4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
((a3,a1,a2,a0) . w4) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . w4))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . w4)))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized ((a3,a1,a2,a0) . w4)),((LifeSpan (((a0 +* (while>0 (a2,a1))) +* a1),(Initialized ((a3,a1,a2,a0) . w4)))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC ((a3,a1,a2,a0) . body3) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((a3,a1,a2,a0) . body3) . (IC ) is set
body3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(a3,a1,a2,a0) . (body3 + 1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total Element of product (the_Values_of SCM+FSA)
m2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),m2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
m2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),m2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
m3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),m3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
m1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a2,a1))),(Initialized ((a3,a1,a2,a0) . body3)),m1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) . (IC ) is set
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
body3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) . (IC ) is set
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a2,a1))),(Initialized a3),i5)) . (IC ) is set
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
i5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
dom (while>0 (a2,a1)) is non empty V53() countable V132() set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
a1 is V111() non read-only Element of the carrier of SCM+FSA
while>0 (a1,a0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
a3 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a4 . a1 is ext-real V36() V37() integer set
a3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a5 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialized a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a4 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a5 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a5 +* (while>0 (a1,a0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a5 +* a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a5 +* a0),(Initialized a4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a5 +* a0),(Initialized a4))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a5 +* a0),(Initialized a4),(LifeSpan ((a5 +* a0),(Initialized a4)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a5 +* a0),(Initialized a4),(LifeSpan ((a5 +* a0),(Initialized a4))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a5 +* a0),(Initialized a4),(LifeSpan ((a5 +* a0),(Initialized a4))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) . (intloc 0) is ext-real V36() V37() integer set
(Comput ((a5 +* a0),(Initialized a4),(LifeSpan ((a5 +* a0),(Initialized a4))))) . (intloc 0) is ext-real V36() V37() integer set
Result ((a5 +* a0),(Initialized a4)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Result ((a5 +* a0),(Initialized a4))) . (intloc 0) is ext-real V36() V37() integer set
IExec (a0,a5,a4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (a0,a5,a4)) . (intloc 0) is ext-real V36() V37() integer set
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) . a1 is ext-real V36() V37() integer set
(Comput ((a5 +* a0),(Initialized a4),(LifeSpan ((a5 +* a0),(Initialized a4))))) . a1 is ext-real V36() V37() integer set
(Result ((a5 +* a0),(Initialized a4))) . a1 is ext-real V36() V37() integer set
(IExec (a0,a5,a4)) . a1 is ext-real V36() V37() integer set
(a5 +* (while>0 (a1,a0))) +* (while>0 (a1,a0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialized (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
IC (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))) . (IC ) is set
b6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))),b6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))),b6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))),b6)) . (IC ) is set
(a5 +* (while>0 (a1,a0))) /. (IC (Comput ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),((LifeSpan ((a5 +* a0),(Initialized a4))) + 3))),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
((LifeSpan ((a5 +* a0),(Initialized a4))) + 3) + b6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
i1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),i1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),i1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),i1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),i1)) . (IC ) is set
(a5 +* (while>0 (a1,a0))) /. (IC (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),i1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
b6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),b6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a5 +* (while>0 (a1,a0))),(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),b6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),b6)) . (IC ) is set
(a5 +* (while>0 (a1,a0))) /. (IC (Comput ((a5 +* (while>0 (a1,a0))),(Initialized a4),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a4 . a1 is ext-real V36() V37() integer set
a5 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a1 is ext-real V36() V37() integer set
a4 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a1 is ext-real V36() V37() integer set
a4 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a1 is ext-real V36() V37() integer set
a4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a5 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a5 . a1 is ext-real V36() V37() integer set
a6 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a5 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a3 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a1 is ext-real V36() V37() integer set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
a1 is V111() non read-only Element of the carrier of SCM+FSA
while>0 (a1,a0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
a2 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a2 . a1 is ext-real V36() V37() integer set
a3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec (a0,a3,a2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (a0,a3,a2)) . a1 is ext-real V36() V37() integer set
a3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec (a0,a3,a2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (a0,a3,a2)) . a1 is ext-real V36() V37() integer set
a3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec (a0,a3,a2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (a0,a3,a2)) . a1 is ext-real V36() V37() integer set
K33((product (the_Values_of SCM+FSA)),INT) is Relation-like set
K32(K33((product (the_Values_of SCM+FSA)),INT)) is cup-closed diff-closed preBoolean set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
a1 is V111() non read-only Element of the carrier of SCM+FSA
while>0 (a1,a0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
a3 is non empty Relation-like product (the_Values_of SCM+FSA) -defined INT -valued Function-like total V18( product (the_Values_of SCM+FSA), INT ) V38() V39() V40() Element of K32(K33((product (the_Values_of SCM+FSA)),INT))
a4 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a5 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a5 is ext-real V36() V37() integer set
a4 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
a6 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialized a5 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a5 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a6 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a6 +* (while>0 (a1,a0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a6 +* a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a6 +* a0),(Initialized a5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a6 +* a0),(Initialized a5))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a6 +* a0),(Initialized a5),(LifeSpan ((a6 +* a0),(Initialized a5)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a5 . a1 is ext-real V36() V37() integer set
DataPart (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a6 +* a0),(Initialized a5),(LifeSpan ((a6 +* a0),(Initialized a5))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a6 +* a0),(Initialized a5),(LifeSpan ((a6 +* a0),(Initialized a5))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) . (intloc 0) is ext-real V36() V37() integer set
(Comput ((a6 +* a0),(Initialized a5),(LifeSpan ((a6 +* a0),(Initialized a5))))) . (intloc 0) is ext-real V36() V37() integer set
Result ((a6 +* a0),(Initialized a5)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Result ((a6 +* a0),(Initialized a5))) . (intloc 0) is ext-real V36() V37() integer set
IExec (a0,a6,a5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (a0,a6,a5)) . (intloc 0) is ext-real V36() V37() integer set
DataPart (Result ((a6 +* a0),(Initialized a5))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Result ((a6 +* a0),(Initialized a5))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (IExec (a0,a6,a5)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec (a0,a6,a5)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
a3 . (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) is ext-real V36() V37() integer set
a3 . (IExec (a0,a6,a5)) is ext-real V36() V37() integer set
(a6 +* (while>0 (a1,a0))) +* (while>0 (a1,a0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Initialized (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
IC (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))) . (IC ) is set
b6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))),b6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))),b6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))),b6)) . (IC ) is set
(a6 +* (while>0 (a1,a0))) /. (IC (Comput ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),((LifeSpan ((a6 +* a0),(Initialized a5))) + 3))),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
((LifeSpan ((a6 +* a0),(Initialized a5))) + 3) + b6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
i1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),i1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),i1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),i1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),i1)) . (IC ) is set
(a6 +* (while>0 (a1,a0))) /. (IC (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),i1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
b6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),b6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a6 +* (while>0 (a1,a0))),(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),b6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),b6)) . (IC ) is set
(a6 +* (while>0 (a1,a0))) /. (IC (Comput ((a6 +* (while>0 (a1,a0))),(Initialized a5),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
a5 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a5 is ext-real V36() V37() integer set
a6 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a4 is ext-real V36() V37() integer set
a5 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a4 . a1 is ext-real V36() V37() integer set
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a4 is ext-real V36() V37() integer set
a4 . a1 is ext-real V36() V37() integer set
a5 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a4 is ext-real V36() V37() integer set
a5 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
a6 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a6 is ext-real V36() V37() integer set
initializeWorkMem is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a6 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a4 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 . a4 is ext-real V36() V37() integer set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
DataPart (Initialized a1) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Initialized a1) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a3 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a3 is ext-real V36() V37() integer set
while>0 (a3,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
IExec ((while>0 (a3,a2)),a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (IExec ((while>0 (a3,a2)),a0,a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a3,a2)),a0,a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Initialize (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a0 +* (while>0 (a3,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 >0_goto 4 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
dom (while>0 (a3,a2)) is non empty V53() countable V132() set
(a0 +* (while>0 (a3,a2))) . 1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . 1 is set
dom (Start-At (0,SCM+FSA)) is non empty V53() countable set
IC (Initialize (Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Initialize (Initialized a1)) . (IC ) is set
IC (Start-At (0,SCM+FSA)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Start-At (0,SCM+FSA)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) . 0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . 0 is set
CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) /. (IC (Initialize (Initialized a1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(0 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),0)) is set
Following ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)))),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))))) . (Initialize (Initialized a1)) is set
Exec ((a3 >0_goto 4),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (a3 >0_goto 4) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (a3 >0_goto 4)) . (Initialize (Initialized a1)) is set
card a2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card a2) + 5 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(a0 +* (while>0 (a3,a2))) . 2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . 2 is set
(Initialize (Initialized a1)) . a3 is ext-real V36() V37() integer set
(Initialized a1) . a3 is ext-real V36() V37() integer set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) . (IC ) is set
succ 0 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
1 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(1 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) is set
Exec ((goto 2),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 2) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 2)) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) is set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) . (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
2 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(2 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)) is set
Exec ((goto 3),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 3) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 3)) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)) is set
(a0 +* (while>0 (a3,a2))) . 3 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . 3 is set
goto ((card a2) + 5) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) . (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),(3 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Following ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)) is set
Exec ((goto ((card a2) + 5)),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto ((card a2) + 5)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto ((card a2) + 5))) . (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)) is set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) . (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(a0 +* (while>0 (a3,a2))) . ((card a2) + 5) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(while>0 (a3,a2)) . ((card a2) + 5) is set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
b6 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),b6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
CurInstr ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),b6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),b6)) . (IC ) is set
(a0 +* (while>0 (a3,a2))) /. (IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),b6))) is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Initialized (Initialized a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized a1) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Initialize (Initialized (Initialized a1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized (Initialized a1)) +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
b6 is V111() Element of the carrier of SCM+FSA
(Initialized a1) . b6 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) . b6 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)) . b6 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)) . b6 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4)) . b6 is ext-real V36() V37() integer set
b6 is FinSeq-Location
(Initialized a1) . b6 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),1)) . b6 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),2)) . b6 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),3)) . b6 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4)) . b6 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((while>0 (a3,a2)),a0,(Initialized a1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (IExec ((while>0 (a3,a2)),a0,(Initialized a1))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a3,a2)),a0,(Initialized a1))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Result ((a0 +* (while>0 (a3,a2))),(Initialized (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Result ((a0 +* (while>0 (a3,a2))),(Initialized (Initialized a1)))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Result ((a0 +* (while>0 (a3,a2))),(Initialized (Initialized a1)))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Result ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Result ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Result ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialize (Initialized a1)),4)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
IExec (a2,a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a3 is ext-real V36() V37() integer set
while>0 (a3,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
IExec ((while>0 (a3,a2)),a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (IExec ((while>0 (a3,a2)),a0,a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a3,a2)),a0,a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
IExec ((while>0 (a3,a2)),a0,(IExec (a2,a0,a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (IExec ((while>0 (a3,a2)),a0,(IExec (a2,a0,a1)))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a3,a2)),a0,(IExec (a2,a0,a1)))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a0 +* a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a0 +* (while>0 (a3,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan ((a0 +* a2),(Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(a0 +* a2) +* (while>0 (a3,a2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(LifeSpan ((a0 +* a2),(Initialized a1))) + 3 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))),((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))),((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1)))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))),((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1)))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Comput (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))),(LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))),(LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))),(LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
IC (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . (IC ) is set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
{(intloc 0),(IC )} is non empty V53() countable set
i1 is FinSeq-Location
(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . i1 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . (intloc 0) is ext-real V36() V37() integer set
i1 is V111() Element of the carrier of SCM+FSA
(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))) . i1 is ext-real V36() V37() integer set
(Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))) . i1 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . i1 is ext-real V36() V37() integer set
i1 is V111() Element of the carrier of SCM+FSA
(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))) . i1 is ext-real V36() V37() integer set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) . i1 is ext-real V36() V37() integer set
i1 is V111() Element of the carrier of SCM+FSA
Initialized (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
IC (Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))) . (IC ) is set
Result ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Result (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
LifeSpan ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))),(LifeSpan ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3)))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))),(LifeSpan ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))),(LifeSpan ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Result ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Result ((a0 +* (while>0 (a3,a2))),(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),((LifeSpan ((a0 +* a2),(Initialized a1))) + 3))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
DataPart (Result (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Result (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
Result ((a0 +* a2),(Initialized a1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized (IExec (a2,a0,a1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(IExec (a2,a0,a1)) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Result ((a0 +* (while>0 (a3,a2))),(Initialized (IExec (a2,a0,a1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Result (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
((LifeSpan ((a0 +* a2),(Initialized a1))) + 3) + (LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(((LifeSpan ((a0 +* a2),(Initialized a1))) + 3) + (LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1))))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Result ((a0 +* (while>0 (a3,a2))),(Initialized a1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),(LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
((LifeSpan ((a0 +* a2),(Initialized a1))) + 3) + ((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1)))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),(((LifeSpan ((a0 +* a2),(Initialized a1))) + 3) + ((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1)))))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
DataPart (Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),(((LifeSpan ((a0 +* a2),(Initialized a1))) + 3) + ((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1))))))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Comput ((a0 +* (while>0 (a3,a2))),(Initialized a1),(((LifeSpan ((a0 +* a2),(Initialized a1))) + 3) + ((LifeSpan (((a0 +* a2) +* (while>0 (a3,a2))),(Initialized (Comput ((a0 +* a2),(Initialized a1),(LifeSpan ((a0 +* a2),(Initialized a1)))))))) + (LifeSpan ((a0 +* (while>0 (a3,a2))),(Initialized a1))))))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a3 is FinSeq-Location
a1 . a3 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
a4 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a4 is ext-real V36() V37() integer set
while>0 (a4,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
IExec ((while>0 (a4,a2)),a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 (a4,a2)),a0,a1)) . a3 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
DataPart (IExec ((while>0 (a4,a2)),a0,a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a4,a2)),a0,a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (IExec ((while>0 (a4,a2)),a0,a1))) . a3 is set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
DataPart (Initialized a1) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Initialized a1) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (Initialized a1)) . a3 is set
(Initialized a1) . a3 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
a1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
a3 is V111() Element of the carrier of SCM+FSA
(Initialized a1) . a3 is ext-real V36() V37() integer set
a4 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a4 is ext-real V36() V37() integer set
while>0 (a4,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
IExec ((while>0 (a4,a2)),a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 (a4,a2)),a0,a1)) . a3 is ext-real V36() V37() integer set
DataPart (IExec ((while>0 (a4,a2)),a0,a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a4,a2)),a0,a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (IExec ((while>0 (a4,a2)),a0,a1))) . a3 is set
DataPart (Initialized a1) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(Initialized a1) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (Initialized a1)) . a3 is set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
IExec (a2,a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 is FinSeq-Location
a4 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a4 is ext-real V36() V37() integer set
while>0 (a4,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
IExec ((while>0 (a4,a2)),a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 (a4,a2)),a0,a1)) . a3 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1)))) . a3 is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
DataPart (IExec ((while>0 (a4,a2)),a0,a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a4,a2)),a0,a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (IExec ((while>0 (a4,a2)),a0,a1))) . a3 is set
DataPart (IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1)))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1)))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1))))) . a3 is set
a0 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
a1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
IExec (a2,a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
a3 is V111() Element of the carrier of SCM+FSA
a4 is V111() non read-only Element of the carrier of SCM+FSA
a1 . a4 is ext-real V36() V37() integer set
while>0 (a4,a2) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
IExec ((while>0 (a4,a2)),a0,a1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 (a4,a2)),a0,a1)) . a3 is ext-real V36() V37() integer set
IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1)))) . a3 is ext-real V36() V37() integer set
DataPart (IExec ((while>0 (a4,a2)),a0,a1)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a4,a2)),a0,a1)) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (IExec ((while>0 (a4,a2)),a0,a1))) . a3 is set
DataPart (IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1)))) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible data-only set
(IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1)))) | (NonZero SCM+FSA) is Relation-like the carrier of SCM+FSA -defined NonZero SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible set
(DataPart (IExec ((while>0 (a4,a2)),a0,(IExec (a2,a0,a1))))) . a3 is set
intloc 1 is V111() Element of the carrier of SCM+FSA
intloc 2 is V111() Element of the carrier of SCM+FSA
intloc 3 is V111() Element of the carrier of SCM+FSA
intloc 4 is V111() Element of the carrier of SCM+FSA
intloc 5 is V111() Element of the carrier of SCM+FSA
intloc 6 is V111() Element of the carrier of SCM+FSA
(intloc 2) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc 3) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 4) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
f0 is FinSeq-Location
(intloc 1) :=len f0 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 1),f0*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 1),f0*>) is set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len f0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
SubFrom ((intloc 1),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len f0)) ";" (SubFrom ((intloc 1),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 2) :=len f0 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 2),f0*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 2),f0*>) is set
SubFrom ((intloc 2),(intloc 1)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 3) := (intloc 2) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
AddTo ((intloc 3),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := (f0,(intloc 3)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),f0,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 6),f0,(intloc 3)*>) is set
(((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
SubFrom ((intloc 4),(intloc 4)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := (f0,(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),f0,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 5),f0,(intloc 2)*>) is set
SubFrom ((intloc 5),(intloc 6)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
SubFrom ((intloc 2),(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
Macro (SubFrom ((intloc 2),(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
K331(SCM+FSA,(SubFrom ((intloc 2),(intloc 2)))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
stop K331(SCM+FSA,(SubFrom ((intloc 2),(intloc 2)))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
AddTo ((intloc 4),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
SubFrom ((intloc 2),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(intloc 2) := (intloc 3) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
SubFrom ((intloc 3),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(f0,(intloc 2)) := (intloc 6) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),f0,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 6),f0,(intloc 2)*>) is set
(((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(f0,(intloc 3)) := (intloc 5) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),f0,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 5),f0,(intloc 3)*>) is set
((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Times ((intloc 1),(((((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len f0)) ";" (SubFrom ((intloc 1),(intloc 0)))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((fsloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(intloc 1) :=len (fsloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 1),(fsloc 0)*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 1),(fsloc 0)*>) is set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len (fsloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len (fsloc 0))) ";" (SubFrom ((intloc 1),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 2) :=len (fsloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 2),(fsloc 0)*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 2),(fsloc 0)*>) is set
((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := ((fsloc 0),(intloc 3)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),(fsloc 0),(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 6),(fsloc 0),(intloc 3)*>) is set
(((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := ((fsloc 0),(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),(fsloc 0),(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 5),(fsloc 0),(intloc 2)*>) is set
((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((fsloc 0),(intloc 2)) := (intloc 6) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),(fsloc 0),(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 6),(fsloc 0),(intloc 2)*>) is set
(((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((fsloc 0),(intloc 3)) := (intloc 5) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),(fsloc 0),(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 5),(fsloc 0),(intloc 3)*>) is set
((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len (fsloc 0))) ";" (SubFrom ((intloc 1),(intloc 0)))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
() is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
{(intloc 0),(intloc 1),(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} is V53() countable set
UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is V53() countable Element of K32(Int-Locations)
i4 is FinSeq-Location
(i4) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(intloc 1) :=len i4 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 1),i4*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 1),i4*>) is set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 2) :=len i4 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 2),i4*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 2),i4*>) is set
((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := (i4,(intloc 3)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),i4,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 6),i4,(intloc 3)*>) is set
(((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := (i4,(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),i4,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 5),i4,(intloc 2)*>) is set
((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(i4,(intloc 2)) := (intloc 6) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),i4,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 6),i4,(intloc 2)*>) is set
(((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(i4,(intloc 3)) := (intloc 5) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),i4,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 5),i4,(intloc 3)*>) is set
((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0)))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
UsedIntLoc (i4) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((i4,(intloc 3)) := (intloc 5)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6)))) \/ (UsedIntLoc ((i4,(intloc 3)) := (intloc 5))) is V53() countable set
{(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6)))) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((i4,(intloc 2)) := (intloc 6)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ (UsedIntLoc ((i4,(intloc 2)) := (intloc 6))) is V53() countable set
((UsedIntLoc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ (UsedIntLoc ((i4,(intloc 2)) := (intloc 6)))) \/ {(intloc 3),(intloc 5)} is non empty V53() countable set
{(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 6) := (i4,(intloc 3))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ (UsedIntLoc ((intloc 6) := (i4,(intloc 3)))) is V53() countable set
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ (UsedIntLoc ((intloc 6) := (i4,(intloc 3))))) \/ {(intloc 2),(intloc 6)} is non empty V53() countable set
(((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ (UsedIntLoc ((intloc 6) := (i4,(intloc 3))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable set
{(intloc 6),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 3)}) \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 3)}) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 3)} \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ ({(intloc 6),(intloc 3)} \/ {(intloc 2),(intloc 6)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ ({(intloc 6),(intloc 3)} \/ {(intloc 2),(intloc 6)})) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 3),(intloc 2),(intloc 6)} is V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 3),(intloc 2),(intloc 6)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 3),(intloc 2),(intloc 6)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 6),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 6),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 6),(intloc 2),(intloc 3)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2),(intloc 3)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 2)} \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ ({(intloc 6),(intloc 2)} \/ {(intloc 3)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ ({(intloc 6),(intloc 2)} \/ {(intloc 3)})) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)}) \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)}) \/ {(intloc 3)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)}) \/ ({(intloc 3)} \/ {(intloc 3),(intloc 5)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 5)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)}) \/ {(intloc 3),(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 5) := (i4,(intloc 2))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedIntLoc ((intloc 5) := (i4,(intloc 2)))) is V53() countable set
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedIntLoc ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)} is non empty V53() countable set
(((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedIntLoc ((intloc 5) := (i4,(intloc 2))))) \/ {(intloc 6),(intloc 2)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable set
{(intloc 5),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 5),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 5),(intloc 2)}) \/ {(intloc 6),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 5),(intloc 2)}) \/ {(intloc 6),(intloc 2)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2)} \/ {(intloc 6),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ ({(intloc 5),(intloc 2)} \/ {(intloc 6),(intloc 2)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ ({(intloc 5),(intloc 2)} \/ {(intloc 6),(intloc 2)})) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6),(intloc 2)} is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 5),(intloc 2),(intloc 6),(intloc 2)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 5),(intloc 2),(intloc 6),(intloc 2)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 6),(intloc 5)} is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 2),(intloc 6),(intloc 5)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 2),(intloc 6),(intloc 5)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 6),(intloc 5)} is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6),(intloc 5)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6),(intloc 5)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 6)} \/ {(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ ({(intloc 2),(intloc 6)} \/ {(intloc 5)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ ({(intloc 2),(intloc 6)} \/ {(intloc 5)})) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5)}) \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5)} \/ {(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ ({(intloc 5)} \/ {(intloc 3),(intloc 5)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 3),(intloc 5)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 5),(intloc 3)} is V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 2) := (intloc 3)) is V53() countable Element of Fin Int-Locations
UsedIntLoc (SubFrom ((intloc 3),(intloc 0))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((intloc 2) := (intloc 3))) \/ (UsedIntLoc (SubFrom ((intloc 3),(intloc 0)))) is V53() countable Element of Fin Int-Locations
((UsedIntLoc ((intloc 2) := (intloc 3))) \/ (UsedIntLoc (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)} is non empty V53() countable set
(((UsedIntLoc ((intloc 2) := (intloc 3))) \/ (UsedIntLoc (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable set
{(intloc 2),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3)} \/ (UsedIntLoc (SubFrom ((intloc 3),(intloc 0)))) is non empty V53() countable set
({(intloc 2),(intloc 3)} \/ (UsedIntLoc (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)} is non empty V53() countable set
(({(intloc 2),(intloc 3)} \/ (UsedIntLoc (SubFrom ((intloc 3),(intloc 0))))) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable set
{(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3)} \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 3)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 3)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 3),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 3),(intloc 0)} \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 3),(intloc 3),(intloc 0)} \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 2),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 3),(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 0)}) \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3)} \/ {(intloc 2),(intloc 0)}) \/ {(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ ({(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ ({(intloc 2),(intloc 0)} \/ {(intloc 2),(intloc 6)})) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0),(intloc 2),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 0),(intloc 2),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 0),(intloc 2),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 0),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 2),(intloc 0),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 2),(intloc 0),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 0),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 0),(intloc 6)}) \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 5),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 5),(intloc 3)}) \/ {(intloc 2),(intloc 0),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5),(intloc 3)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5),(intloc 3)} \/ {(intloc 2),(intloc 0),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 5)} \/ {(intloc 2),(intloc 0),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5)} \/ {(intloc 2),(intloc 0),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (Macro (SubFrom ((intloc 2),(intloc 2)))) is V53() countable Element of K32(Int-Locations)
{(intloc 5)} \/ (UsedIntLoc (Macro (SubFrom ((intloc 2),(intloc 2))))) is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))) is V53() countable Element of K32(Int-Locations)
({(intloc 5)} \/ (UsedIntLoc (Macro (SubFrom ((intloc 2),(intloc 2)))))) \/ (UsedIntLoc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (SubFrom ((intloc 2),(intloc 2))) is V53() countable Element of Fin Int-Locations
{(intloc 5)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 2)))) is non empty V53() countable set
({(intloc 5)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 2))))) \/ (UsedIntLoc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is non empty V53() countable set
{(intloc 2),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5)} \/ {(intloc 2),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5)} \/ {(intloc 2),(intloc 2)}) \/ (UsedIntLoc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (AddTo ((intloc 4),(intloc 0))) is V53() countable Element of Fin Int-Locations
UsedIntLoc (SubFrom ((intloc 2),(intloc 0))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (AddTo ((intloc 4),(intloc 0)))) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 0)))) is V53() countable Element of Fin Int-Locations
({(intloc 5)} \/ {(intloc 2),(intloc 2)}) \/ ((UsedIntLoc (AddTo ((intloc 4),(intloc 0)))) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 0))))) is non empty V53() countable set
{(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 4),(intloc 0)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 0)))) is non empty V53() countable set
({(intloc 5)} \/ {(intloc 2),(intloc 2)}) \/ ({(intloc 4),(intloc 0)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 0))))) is non empty V53() countable set
{(intloc 4),(intloc 0)} \/ {(intloc 2),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5)} \/ {(intloc 2),(intloc 2)}) \/ ({(intloc 4),(intloc 0)} \/ {(intloc 2),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5)} \/ {(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5)} \/ {(intloc 2)}) \/ ({(intloc 4),(intloc 0)} \/ {(intloc 2),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5)} \/ {(intloc 2)}) \/ {(intloc 2),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 5)} \/ {(intloc 2)}) \/ {(intloc 2),(intloc 0)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5)} \/ {(intloc 2),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 5)} \/ {(intloc 2),(intloc 0)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 2),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 2),(intloc 0)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 0)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 0)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 0),(intloc 4),(intloc 0)} is V53() countable set
{(intloc 5),(intloc 0),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 5),(intloc 0),(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 0),(intloc 4),(intloc 5)} is V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 0),(intloc 0),(intloc 4),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 4),(intloc 5)} is V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 0),(intloc 4),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0),(intloc 4),(intloc 5)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 6) := (intloc 0)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0)))) \/ (UsedIntLoc ((intloc 6) := (intloc 0))) is V53() countable set
{(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0)))) \/ {(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 5) := (intloc 0)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)))) \/ (UsedIntLoc ((intloc 5) := (intloc 0))) is V53() countable set
((UsedIntLoc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)))) \/ (UsedIntLoc ((intloc 5) := (intloc 0)))) \/ {(intloc 6),(intloc 0)} is non empty V53() countable set
{(intloc 5),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)))) \/ {(intloc 5),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)))) \/ {(intloc 5),(intloc 0)}) \/ {(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 4) := (intloc 0)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ (UsedIntLoc ((intloc 4) := (intloc 0))) is V53() countable set
((UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ (UsedIntLoc ((intloc 4) := (intloc 0)))) \/ {(intloc 5),(intloc 0)} is non empty V53() countable set
(((UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ (UsedIntLoc ((intloc 4) := (intloc 0)))) \/ {(intloc 5),(intloc 0)}) \/ {(intloc 6),(intloc 0)} is non empty V53() countable set
(UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)}) \/ {(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 2) := (intloc 0)) is V53() countable Element of Fin Int-Locations
UsedIntLoc ((intloc 3) := (intloc 0)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((intloc 2) := (intloc 0))) \/ (UsedIntLoc ((intloc 3) := (intloc 0))) is V53() countable Element of Fin Int-Locations
((UsedIntLoc ((intloc 2) := (intloc 0))) \/ (UsedIntLoc ((intloc 3) := (intloc 0)))) \/ {(intloc 4),(intloc 0)} is non empty V53() countable set
(((UsedIntLoc ((intloc 2) := (intloc 0))) \/ (UsedIntLoc ((intloc 3) := (intloc 0)))) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)} is non empty V53() countable set
((((UsedIntLoc ((intloc 2) := (intloc 0))) \/ (UsedIntLoc ((intloc 3) := (intloc 0)))) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)}) \/ {(intloc 6),(intloc 0)} is non empty V53() countable set
(UsedIntLoc ((intloc 2) := (intloc 0))) \/ {(intloc 3),(intloc 0)} is non empty V53() countable set
((UsedIntLoc ((intloc 2) := (intloc 0))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable set
(((UsedIntLoc ((intloc 2) := (intloc 0))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)} is non empty V53() countable set
((((UsedIntLoc ((intloc 2) := (intloc 0))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)}) \/ {(intloc 6),(intloc 0)} is non empty V53() countable set
{(intloc 2),(intloc 0)} \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 0)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 0)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
((({(intloc 2),(intloc 0)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 5),(intloc 0)}) \/ {(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 0)} \/ {(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 0)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)}) \/ ({(intloc 5),(intloc 0)} \/ {(intloc 6),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 5),(intloc 6)} is V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 0)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 4),(intloc 0)}) \/ {(intloc 0),(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0)}) \/ {(intloc 0),(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0)} \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0)}) \/ ({(intloc 0)} \/ {(intloc 5),(intloc 6)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0)}) \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0)}) \/ {(intloc 0)}) \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 4),(intloc 0)} \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3)} \/ ({(intloc 4),(intloc 0)} \/ {(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ ({(intloc 4),(intloc 0)} \/ {(intloc 0)})) \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 4),(intloc 0),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0),(intloc 0)} is V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4),(intloc 0),(intloc 0)}) \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 0)} \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3)} \/ ({(intloc 0),(intloc 0)} \/ {(intloc 4)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ ({(intloc 0),(intloc 0)} \/ {(intloc 4)})) \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 0),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 0),(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 0),(intloc 0)}) \/ {(intloc 4)}) \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 0),(intloc 0),(intloc 2),(intloc 3)} is V53() countable set
{(intloc 0),(intloc 0),(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4)} is non empty V53() countable set
({(intloc 0),(intloc 0),(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4)}) \/ {(intloc 5),(intloc 6)} is non empty V53() countable set
{(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 2),(intloc 3)} \/ {(intloc 4)}) \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3),(intloc 4)} is V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3),(intloc 4)} \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} is V53() countable set
{(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} is V53() countable set
{(intloc 0)} \/ {(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} is non empty V53() countable set
UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (SubFrom ((intloc 4),(intloc 4))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ (UsedIntLoc (SubFrom ((intloc 4),(intloc 4)))) is V53() countable set
{(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ (UsedIntLoc ((intloc 6) := (i4,(intloc 3)))) is V53() countable set
((UsedIntLoc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ (UsedIntLoc ((intloc 6) := (i4,(intloc 3))))) \/ {(intloc 4),(intloc 4)} is non empty V53() countable set
{(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (AddTo ((intloc 3),(intloc 0))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ (UsedIntLoc (AddTo ((intloc 3),(intloc 0)))) is V53() countable set
((UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ (UsedIntLoc (AddTo ((intloc 3),(intloc 0))))) \/ {(intloc 3),(intloc 6)} is non empty V53() countable set
(((UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ (UsedIntLoc (AddTo ((intloc 3),(intloc 0))))) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable set
(UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 3) := (intloc 2)) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedIntLoc ((intloc 3) := (intloc 2))) is V53() countable set
((UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedIntLoc ((intloc 3) := (intloc 2)))) \/ {(intloc 3),(intloc 0)} is non empty V53() countable set
(((UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedIntLoc ((intloc 3) := (intloc 2)))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable set
((((UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedIntLoc ((intloc 3) := (intloc 2)))) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable set
{(intloc 3),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
((((UsedIntLoc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 2) :=len i4) is V53() countable Element of Fin Int-Locations
UsedIntLoc (SubFrom ((intloc 2),(intloc 1))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((intloc 2) :=len i4)) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1)))) is V53() countable Element of Fin Int-Locations
((UsedIntLoc ((intloc 2) :=len i4)) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)} is non empty V53() countable set
(((UsedIntLoc ((intloc 2) :=len i4)) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)} is non empty V53() countable set
((((UsedIntLoc ((intloc 2) :=len i4)) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable set
(((((UsedIntLoc ((intloc 2) :=len i4)) \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable set
{(intloc 2)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1)))) is non empty V53() countable set
({(intloc 2)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)} is non empty V53() countable set
(({(intloc 2)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)} is non empty V53() countable set
((({(intloc 2)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable set
(((({(intloc 2)} \/ (UsedIntLoc (SubFrom ((intloc 2),(intloc 1))))) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable set
{(intloc 2),(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 2),(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2)} \/ {(intloc 2),(intloc 1)}) \/ {(intloc 3),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2)} \/ {(intloc 2),(intloc 1)}) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
((({(intloc 2)} \/ {(intloc 2),(intloc 1)}) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(((({(intloc 2)} \/ {(intloc 2),(intloc 1)}) \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
((({(intloc 2),(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
((({(intloc 2),(intloc 1)} \/ {(intloc 3),(intloc 2)}) \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 1),(intloc 3),(intloc 2)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 1),(intloc 3),(intloc 2)} \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 1),(intloc 3),(intloc 2)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 1),(intloc 3),(intloc 2)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 3),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 3),(intloc 1)} \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 2),(intloc 3),(intloc 1)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 2),(intloc 3),(intloc 1)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 1)} \/ {(intloc 3),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 3),(intloc 1)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 3),(intloc 1)} \/ {(intloc 3),(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 1),(intloc 3),(intloc 0)} is V53() countable set
{(intloc 2),(intloc 3),(intloc 1),(intloc 3),(intloc 0)} \/ {(intloc 3),(intloc 6)} is non empty V53() countable set
({(intloc 2),(intloc 3),(intloc 1),(intloc 3),(intloc 0)} \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable set
{(intloc 2),(intloc 3),(intloc 1),(intloc 3)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 1),(intloc 3)} \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 3),(intloc 1),(intloc 3)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 2),(intloc 3),(intloc 1),(intloc 3)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 1),(intloc 2)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 1),(intloc 2)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 0)}) \/ {(intloc 3),(intloc 6)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 3),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 3),(intloc 6)}) \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 1),(intloc 2)} \/ {(intloc 3),(intloc 6)}) \/ {(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 1),(intloc 2),(intloc 3),(intloc 6)} is V53() countable set
{(intloc 3),(intloc 1),(intloc 2),(intloc 3),(intloc 6)} \/ {(intloc 0)} is non empty V53() countable set
({(intloc 3),(intloc 1),(intloc 2),(intloc 3),(intloc 6)} \/ {(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable set
{(intloc 3),(intloc 1),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
{(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 1),(intloc 2),(intloc 3)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 1),(intloc 2),(intloc 3)} \/ {(intloc 6)}) \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 1),(intloc 2),(intloc 3)} \/ {(intloc 6)}) \/ {(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 2),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6)}) \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6)}) \/ {(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6)}) \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6)}) \/ {(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6)} \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 6)} \/ {(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 6)} \/ {(intloc 0)})) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 0)}) \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 0)} \/ {(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 6),(intloc 0)} \/ {(intloc 4)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 0),(intloc 4)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 0),(intloc 4)} is V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
UsedIntLoc (((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))))) \/ (UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (SubFrom ((intloc 5),(intloc 6))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((intloc 5) := (i4,(intloc 2)))) \/ (UsedIntLoc (SubFrom ((intloc 5),(intloc 6)))) is V53() countable Element of Fin Int-Locations
((UsedIntLoc ((intloc 5) := (i4,(intloc 2)))) \/ (UsedIntLoc (SubFrom ((intloc 5),(intloc 6))))) \/ (UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable set
{(intloc 2),(intloc 5)} \/ (UsedIntLoc (SubFrom ((intloc 5),(intloc 6)))) is non empty V53() countable set
({(intloc 2),(intloc 5)} \/ (UsedIntLoc (SubFrom ((intloc 5),(intloc 6))))) \/ (UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is non empty V53() countable set
{(intloc 2),(intloc 5)} \/ {(intloc 5),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 5)} \/ {(intloc 5),(intloc 6)}) \/ (UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 5),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 5),(intloc 6)} \/ (UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 5),(intloc 2),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 5),(intloc 2),(intloc 6)} \/ (UsedIntLoc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6)} \/ ({(intloc 2),(intloc 5)} \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 2),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 2),(intloc 5)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 5),(intloc 2),(intloc 6)} is V53() countable set
{(intloc 2),(intloc 5),(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable set
{(intloc 2),(intloc 5),(intloc 5),(intloc 2)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 5),(intloc 2)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 5),(intloc 5),(intloc 2)} \/ {(intloc 6)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 5)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 5)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 2),(intloc 5),(intloc 5)} \/ {(intloc 6)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 5)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 5)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 2),(intloc 5),(intloc 5)} \/ {(intloc 6)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 5),(intloc 2)} is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 5),(intloc 2)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5),(intloc 5),(intloc 2)} \/ {(intloc 6)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2)} \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 5),(intloc 2)} \/ {(intloc 6)}) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)} is V53() countable set
UsedIntLoc ((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))) is V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) \/ (UsedIntLoc (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))) is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ (UsedIntLoc (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ (UsedIntLoc (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 2)} is non empty V53() countable set
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 2)}) is non empty V53() countable set
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 2)})) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable set
{(intloc 2),(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)} is V53() countable set
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ {(intloc 2),(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)} is V53() countable set
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ {(intloc 2),(intloc 5),(intloc 2),(intloc 6),(intloc 4),(intloc 0)}) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable set
{(intloc 2),(intloc 5),(intloc 2),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 2),(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 2),(intloc 5),(intloc 2),(intloc 6)} \/ {(intloc 4),(intloc 0)})) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 6)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 2),(intloc 2),(intloc 5),(intloc 6)} \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 2),(intloc 2),(intloc 5),(intloc 6)} \/ {(intloc 4),(intloc 0)})) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 6)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 2),(intloc 5),(intloc 6)} \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 2),(intloc 5),(intloc 6)} \/ {(intloc 4),(intloc 0)})) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 6),(intloc 4),(intloc 0)} is V53() countable set
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ {(intloc 2),(intloc 5),(intloc 6),(intloc 4),(intloc 0)} is V53() countable set
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ {(intloc 2),(intloc 5),(intloc 6),(intloc 4),(intloc 0)}) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable set
{(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 2),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 2),(intloc 5)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ ({(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 2),(intloc 5)})) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 6),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
((({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 6),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 6),(intloc 4),(intloc 0)}) is V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 6),(intloc 4),(intloc 0)})) \/ {(intloc 2),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 6),(intloc 4),(intloc 0)} \/ {(intloc 6),(intloc 4),(intloc 0)})) \/ {(intloc 2),(intloc 5)}) \/ ((UsedIntLoc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0),(intloc 6)} \/ {(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5)} \/ ({(intloc 2),(intloc 0),(intloc 6)} \/ {(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ({(intloc 3),(intloc 5)} \/ ({(intloc 2),(intloc 0),(intloc 6)} \/ {(intloc 4),(intloc 0)})) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0),(intloc 6),(intloc 4),(intloc 0)} is V53() countable set
{(intloc 3),(intloc 5)} \/ {(intloc 2),(intloc 0),(intloc 6),(intloc 4),(intloc 0)} is non empty V53() countable set
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ({(intloc 3),(intloc 5)} \/ {(intloc 2),(intloc 0),(intloc 6),(intloc 4),(intloc 0)}) is non empty V53() countable set
{(intloc 0),(intloc 6),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 0),(intloc 6),(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5)} \/ ({(intloc 2)} \/ {(intloc 0),(intloc 6),(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ({(intloc 3),(intloc 5)} \/ ({(intloc 2)} \/ {(intloc 0),(intloc 6),(intloc 4),(intloc 0)})) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 0),(intloc 4),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 0),(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5)} \/ ({(intloc 2)} \/ {(intloc 0),(intloc 0),(intloc 4),(intloc 6)}) is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ({(intloc 3),(intloc 5)} \/ ({(intloc 2)} \/ {(intloc 0),(intloc 0),(intloc 4),(intloc 6)})) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 4),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 2)} \/ {(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5)} \/ ({(intloc 2)} \/ {(intloc 0),(intloc 4),(intloc 6)}) is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ({(intloc 3),(intloc 5)} \/ ({(intloc 2)} \/ {(intloc 0),(intloc 4),(intloc 6)})) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5)} \/ {(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ ({(intloc 3),(intloc 5)} \/ {(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 6),(intloc 4),(intloc 0)}) \/ {(intloc 2),(intloc 5)}) \/ {(intloc 3),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable set
{(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 0),(intloc 4),(intloc 6)} is V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 5),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 5),(intloc 2)}) \/ {(intloc 3),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable set
{(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 5),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 5),(intloc 2)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 5),(intloc 2)})) \/ {(intloc 3),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable set
{(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
{(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
{(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 3)} is non empty V53() countable set
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) \/ ({(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 3)}) is non empty V53() countable set
({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
(({(intloc 3),(intloc 2),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable set
{(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
{(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)}) is V53() countable set
({(intloc 3),(intloc 2),(intloc 1)} \/ ({(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)})) \/ {(intloc 3)} is non empty V53() countable set
{(intloc 3),(intloc 2),(intloc 1),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
{(intloc 3),(intloc 2),(intloc 1),(intloc 5),(intloc 2),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 3)} is non empty V53() countable set
{(intloc 3),(intloc 2),(intloc 1),(intloc 5),(intloc 2)} is V53() countable set
{(intloc 3),(intloc 2),(intloc 1),(intloc 5),(intloc 2)} \/ {(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
({(intloc 3),(intloc 2),(intloc 1),(intloc 5),(intloc 2)} \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable set
{(intloc 2),(intloc 1),(intloc 5),(intloc 2)} is V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 1),(intloc 5),(intloc 2)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 1),(intloc 5),(intloc 2)}) \/ {(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3)} \/ {(intloc 2),(intloc 1),(intloc 5),(intloc 2)}) \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 2),(intloc 5),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 2),(intloc 5),(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 2),(intloc 5),(intloc 1)}) \/ {(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3)} \/ {(intloc 2),(intloc 2),(intloc 5),(intloc 1)}) \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 5),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 3)} \/ {(intloc 2),(intloc 5),(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 3)} \/ {(intloc 2),(intloc 5),(intloc 1)}) \/ {(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 3)} \/ {(intloc 2),(intloc 5),(intloc 1)}) \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 5),(intloc 1)} is V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 2),(intloc 5),(intloc 1)} \/ {(intloc 0),(intloc 4),(intloc 6)} is V53() countable Element of K32(Int-Locations)
({(intloc 3),(intloc 2),(intloc 5),(intloc 1)} \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1),(intloc 5),(intloc 2),(intloc 3)} is V53() countable Element of K32(Int-Locations)
{(intloc 1),(intloc 5),(intloc 2),(intloc 3)} \/ {(intloc 0),(intloc 4),(intloc 6)} is V53() countable Element of K32(Int-Locations)
({(intloc 1),(intloc 5),(intloc 2),(intloc 3)} \/ {(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1),(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
{(intloc 1),(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 6)} \/ {(intloc 3)} is non empty V53() countable set
{(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 6)} is V53() countable set
{(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 6)} is non empty V53() countable set
({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable set
{(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} is V53() countable set
{(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} \/ {(intloc 6)} is non empty V53() countable set
{(intloc 1)} \/ ({(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} \/ {(intloc 6)}) is non empty V53() countable set
({(intloc 1)} \/ ({(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} \/ {(intloc 6)})) \/ {(intloc 3)} is non empty V53() countable set
{(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} is non empty V53() countable set
({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)}) \/ {(intloc 6)} is non empty V53() countable set
(({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)}) \/ {(intloc 6)}) \/ {(intloc 3)} is non empty V53() countable set
({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)}) \/ {(intloc 3)} is non empty V53() countable set
(({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)}) \/ {(intloc 3)}) \/ {(intloc 6)} is non empty V53() countable set
{(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} \/ {(intloc 3)} is non empty V53() countable set
{(intloc 1)} \/ ({(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} \/ {(intloc 3)}) is non empty V53() countable set
({(intloc 1)} \/ ({(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4)} \/ {(intloc 3)})) \/ {(intloc 6)} is non empty V53() countable set
{(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 3)} is V53() countable set
{(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 3)} is non empty V53() countable set
({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 0),(intloc 4),(intloc 3)}) \/ {(intloc 6)} is non empty V53() countable set
{(intloc 3),(intloc 0),(intloc 4),(intloc 3)} is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 0),(intloc 4),(intloc 3)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1)} \/ ({(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 0),(intloc 4),(intloc 3)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 1)} \/ ({(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 0),(intloc 4),(intloc 3)})) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 3),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 3),(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1)} \/ ({(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 3),(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 1)} \/ ({(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 3),(intloc 4),(intloc 0)})) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 3),(intloc 4),(intloc 0)} is V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 4),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1)} \/ ({(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 4),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 1)} \/ ({(intloc 5),(intloc 2)} \/ {(intloc 3),(intloc 4),(intloc 0)})) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 5),(intloc 2),(intloc 3),(intloc 4),(intloc 0)} is V53() countable set
{(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4),(intloc 0)} is non empty V53() countable set
({(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4),(intloc 0)}) \/ {(intloc 6)} is non empty V53() countable set
{(intloc 5),(intloc 2),(intloc 3),(intloc 4)} is V53() countable Element of K32(Int-Locations)
{(intloc 0)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1)} \/ ({(intloc 0)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)}) is non empty V53() countable Element of K32(Int-Locations)
({(intloc 1)} \/ ({(intloc 0)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)})) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1)} \/ {(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 1)} \/ {(intloc 0)}) \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
(({(intloc 1)} \/ {(intloc 0)}) \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)}) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 1)} \/ {(intloc 5),(intloc 2),(intloc 3),(intloc 4)}) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 4),(intloc 5)} is V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 1)} \/ {(intloc 2),(intloc 3),(intloc 4),(intloc 5)} is non empty V53() countable Element of K32(Int-Locations)
({(intloc 0),(intloc 1)} \/ {(intloc 2),(intloc 3),(intloc 4),(intloc 5)}) \/ {(intloc 6)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 0),(intloc 1),(intloc 2),(intloc 3),(intloc 4),(intloc 5)} is V53() countable set
{(intloc 0),(intloc 1),(intloc 2),(intloc 3),(intloc 4),(intloc 5)} \/ {(intloc 6)} is non empty V53() countable set
UsedIntLoc ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0)))) is V53() countable Element of K32(Int-Locations)
UsedIntLoc (Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))))) is V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0))))) \/ (UsedIntLoc (Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))))) is V53() countable Element of K32(Int-Locations)
{(intloc 1),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) \/ {(intloc 1),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0))))) \/ ((UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) \/ {(intloc 1),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc (SubFrom ((intloc 1),(intloc 0))) is V53() countable Element of Fin Int-Locations
(UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ (UsedIntLoc (SubFrom ((intloc 1),(intloc 0)))) is V53() countable set
((UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ (UsedIntLoc (SubFrom ((intloc 1),(intloc 0))))) \/ ((UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) \/ {(intloc 1),(intloc 0)}) is non empty V53() countable set
(UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ {(intloc 1),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ {(intloc 1),(intloc 0)}) \/ ((UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) \/ {(intloc 1),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ {(intloc 1),(intloc 0)}) \/ {(intloc 1),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(((UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ {(intloc 1),(intloc 0)}) \/ {(intloc 1),(intloc 0)}) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable Element of K32(Int-Locations)
{(intloc 1),(intloc 0)} \/ {(intloc 1),(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
(UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ ({(intloc 1),(intloc 0)} \/ {(intloc 1),(intloc 0)}) is non empty V53() countable Element of K32(Int-Locations)
((UsedIntLoc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ ({(intloc 1),(intloc 0)} \/ {(intloc 1),(intloc 0)})) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable Element of K32(Int-Locations)
UsedIntLoc ((intloc 1) :=len i4) is V53() countable Element of Fin Int-Locations
(UsedIntLoc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) \/ (UsedIntLoc ((intloc 1) :=len i4)) is V53() countable set
((UsedIntLoc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) \/ (UsedIntLoc ((intloc 1) :=len i4))) \/ {(intloc 1),(intloc 0)} is non empty V53() countable set
(((UsedIntLoc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) \/ (UsedIntLoc ((intloc 1) :=len i4))) \/ {(intloc 1),(intloc 0)}) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable set
{(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 0)} is non empty V53() countable set
({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 0)}) \/ {(intloc 1)} is non empty V53() countable set
(({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 0)}) \/ {(intloc 1)}) \/ {(intloc 1),(intloc 0)} is non empty V53() countable set
((({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 0)}) \/ {(intloc 1)}) \/ {(intloc 1),(intloc 0)}) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable set
{(intloc 0)} \/ {(intloc 1)} is non empty V53() countable Element of K32(Int-Locations)
{(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ ({(intloc 0)} \/ {(intloc 1)}) is non empty V53() countable set
({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ ({(intloc 0)} \/ {(intloc 1)})) \/ {(intloc 1),(intloc 0)} is non empty V53() countable set
(({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ ({(intloc 0)} \/ {(intloc 1)})) \/ {(intloc 1),(intloc 0)}) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable set
{(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 1),(intloc 0)} is non empty V53() countable set
({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 1),(intloc 0)}) \/ {(intloc 1),(intloc 0)} is non empty V53() countable set
(({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 1),(intloc 0)}) \/ {(intloc 1),(intloc 0)}) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable set
{(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ ({(intloc 1),(intloc 0)} \/ {(intloc 1),(intloc 0)}) is non empty V53() countable set
({(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ ({(intloc 1),(intloc 0)} \/ {(intloc 1),(intloc 0)})) \/ (UsedIntLoc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty V53() countable set
{(intloc 0),(intloc 1),(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} \/ {(intloc 0),(intloc 1),(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} is V53() countable set
UsedInt*Loc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is V53() countable Element of K32(FinSeq-Locations)
i4 is FinSeq-Location
(i4) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(intloc 1) :=len i4 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 1),i4*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 1),i4*>) is set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 2) :=len i4 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 2),i4*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 2),i4*>) is set
((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := (i4,(intloc 3)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),i4,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 6),i4,(intloc 3)*>) is set
(((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := (i4,(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),i4,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 5),i4,(intloc 2)*>) is set
((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(i4,(intloc 2)) := (intloc 6) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),i4,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 6),i4,(intloc 2)*>) is set
(((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(i4,(intloc 3)) := (intloc 5) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),i4,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 5),i4,(intloc 3)*>) is set
((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0)))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
UsedInt*Loc (i4) is V53() countable Element of K32(FinSeq-Locations)
{i4} is non empty V53() countable set
UsedInt*Loc (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((i4,(intloc 3)) := (intloc 5)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6)))) \/ (UsedInt*Loc ((i4,(intloc 3)) := (intloc 5))) is V53() countable set
(UsedInt*Loc ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6)))) \/ {i4} is non empty V53() countable set
UsedInt*Loc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((i4,(intloc 2)) := (intloc 6)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ (UsedInt*Loc ((i4,(intloc 2)) := (intloc 6))) is V53() countable set
((UsedInt*Loc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ (UsedInt*Loc ((i4,(intloc 2)) := (intloc 6)))) \/ {i4} is non empty V53() countable set
(UsedInt*Loc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ {i4} is non empty V53() countable set
((UsedInt*Loc (((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ {i4}) \/ {i4} is non empty V53() countable set
UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((intloc 6) := (i4,(intloc 3))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ (UsedInt*Loc ((intloc 6) := (i4,(intloc 3)))) is V53() countable set
((UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ (UsedInt*Loc ((intloc 6) := (i4,(intloc 3))))) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ (UsedInt*Loc ((intloc 6) := (i4,(intloc 3))))) \/ {i4}) \/ {i4} is non empty V53() countable set
(UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {i4} is non empty V53() countable set
((UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {i4}) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc ((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2))))) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((intloc 5) := (i4,(intloc 2))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedInt*Loc ((intloc 5) := (i4,(intloc 2)))) is V53() countable set
((UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedInt*Loc ((intloc 5) := (i4,(intloc 2))))) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedInt*Loc ((intloc 5) := (i4,(intloc 2))))) \/ {i4}) \/ {i4} is non empty V53() countable set
((((UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ (UsedInt*Loc ((intloc 5) := (i4,(intloc 2))))) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
(UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {i4} is non empty V53() countable set
((UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
((((UsedInt*Loc (((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
UsedInt*Loc ((intloc 2) := (intloc 3)) is V53() countable Element of Fin FinSeq-Locations
UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((intloc 2) := (intloc 3))) \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0)))) is V53() countable Element of Fin FinSeq-Locations
((UsedInt*Loc ((intloc 2) := (intloc 3))) \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc ((intloc 2) := (intloc 3))) \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4} is non empty V53() countable set
((((UsedInt*Loc ((intloc 2) := (intloc 3))) \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
(((((UsedInt*Loc ((intloc 2) := (intloc 3))) \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
{} \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0)))) is V53() countable set
({} \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4} is non empty V53() countable set
(({} \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4} is non empty V53() countable set
((({} \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
(((({} \/ (UsedInt*Loc (SubFrom ((intloc 3),(intloc 0))))) \/ {i4}) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
{} \/ {i4} is non empty V53() countable set
({} \/ {i4}) \/ {i4} is non empty V53() countable set
(({} \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
((({} \/ {i4}) \/ {i4}) \/ {i4}) \/ {i4} is non empty V53() countable set
UsedInt*Loc ((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (Macro (SubFrom ((intloc 2),(intloc 2)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc (Macro (SubFrom ((intloc 2),(intloc 2))))) \/ (UsedInt*Loc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (SubFrom ((intloc 2),(intloc 2))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (SubFrom ((intloc 2),(intloc 2)))) \/ (UsedInt*Loc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is V53() countable set
{} \/ (UsedInt*Loc ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is V53() countable set
UsedInt*Loc (AddTo ((intloc 4),(intloc 0))) is V53() countable Element of Fin FinSeq-Locations
UsedInt*Loc (SubFrom ((intloc 2),(intloc 0))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (AddTo ((intloc 4),(intloc 0)))) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 0)))) is V53() countable Element of Fin FinSeq-Locations
{} \/ ((UsedInt*Loc (AddTo ((intloc 4),(intloc 0)))) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 0))))) is V53() countable set
{} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 0)))) is V53() countable set
{} \/ ({} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 0))))) is V53() countable set
UsedInt*Loc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((intloc 6) := (intloc 0)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0)))) \/ (UsedInt*Loc ((intloc 6) := (intloc 0))) is V53() countable set
(UsedInt*Loc (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0)))) \/ {} is V53() countable set
UsedInt*Loc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((intloc 5) := (intloc 0)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)))) \/ (UsedInt*Loc ((intloc 5) := (intloc 0))) is V53() countable set
(UsedInt*Loc ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0)))) \/ {} is V53() countable set
UsedInt*Loc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((intloc 4) := (intloc 0)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ (UsedInt*Loc ((intloc 4) := (intloc 0))) is V53() countable set
(UsedInt*Loc (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0)))) \/ {} is V53() countable set
UsedInt*Loc ((intloc 2) := (intloc 0)) is V53() countable Element of Fin FinSeq-Locations
UsedInt*Loc ((intloc 3) := (intloc 0)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((intloc 2) := (intloc 0))) \/ (UsedInt*Loc ((intloc 3) := (intloc 0))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((intloc 2) := (intloc 0))) \/ {} is V53() countable set
UsedInt*Loc (((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (SubFrom ((intloc 4),(intloc 4))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ (UsedInt*Loc (SubFrom ((intloc 4),(intloc 4)))) is V53() countable set
(UsedInt*Loc ((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3))))) \/ {} is V53() countable set
UsedInt*Loc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ (UsedInt*Loc ((intloc 6) := (i4,(intloc 3)))) is V53() countable set
((UsedInt*Loc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ (UsedInt*Loc ((intloc 6) := (i4,(intloc 3))))) \/ {} is V53() countable set
(UsedInt*Loc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ {i4} is non empty V53() countable set
((UsedInt*Loc (((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))))) \/ {i4}) \/ {} is non empty V53() countable set
UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (AddTo ((intloc 3),(intloc 0))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ (UsedInt*Loc (AddTo ((intloc 3),(intloc 0)))) is V53() countable set
((UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ (UsedInt*Loc (AddTo ((intloc 3),(intloc 0))))) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ (UsedInt*Loc (AddTo ((intloc 3),(intloc 0))))) \/ {i4}) \/ {} is non empty V53() countable set
(UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ {} is V53() countable set
((UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ {}) \/ {i4} is non empty V53() countable set
(((UsedInt*Loc ((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)))) \/ {}) \/ {i4}) \/ {} is non empty V53() countable set
UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc ((intloc 3) := (intloc 2)) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedInt*Loc ((intloc 3) := (intloc 2))) is V53() countable set
((UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedInt*Loc ((intloc 3) := (intloc 2)))) \/ {} is V53() countable set
(((UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedInt*Loc ((intloc 3) := (intloc 2)))) \/ {}) \/ {i4} is non empty V53() countable set
((((UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ (UsedInt*Loc ((intloc 3) := (intloc 2)))) \/ {}) \/ {i4}) \/ {} is non empty V53() countable set
(UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {} is V53() countable set
((UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {} is V53() countable set
(((UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {}) \/ {i4} is non empty V53() countable set
((((UsedInt*Loc (((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {}) \/ {i4}) \/ {} is non empty V53() countable set
UsedInt*Loc ((intloc 2) :=len i4) is V53() countable Element of Fin FinSeq-Locations
UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((intloc 2) :=len i4)) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1)))) is V53() countable Element of Fin FinSeq-Locations
((UsedInt*Loc ((intloc 2) :=len i4)) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {} is V53() countable set
(((UsedInt*Loc ((intloc 2) :=len i4)) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {} is V53() countable set
((((UsedInt*Loc ((intloc 2) :=len i4)) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {}) \/ {i4} is non empty V53() countable set
(((((UsedInt*Loc ((intloc 2) :=len i4)) \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {}) \/ {i4}) \/ {} is non empty V53() countable set
{i4} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1)))) is non empty V53() countable set
({i4} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {} is non empty V53() countable set
(({i4} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {} is non empty V53() countable set
((({i4} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {}) \/ {i4} is non empty V53() countable set
(((({i4} \/ (UsedInt*Loc (SubFrom ((intloc 2),(intloc 1))))) \/ {}) \/ {}) \/ {i4}) \/ {} is non empty V53() countable set
{i4} \/ {i4} is non empty V53() countable set
({i4} \/ {i4}) \/ {} is non empty V53() countable set
UsedInt*Loc (((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc (((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))))) \/ (UsedInt*Loc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (SubFrom ((intloc 5),(intloc 6))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((intloc 5) := (i4,(intloc 2)))) \/ (UsedInt*Loc (SubFrom ((intloc 5),(intloc 6)))) is V53() countable Element of Fin FinSeq-Locations
((UsedInt*Loc ((intloc 5) := (i4,(intloc 2)))) \/ (UsedInt*Loc (SubFrom ((intloc 5),(intloc 6))))) \/ (UsedInt*Loc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is V53() countable set
{i4} \/ (UsedInt*Loc (SubFrom ((intloc 5),(intloc 6)))) is non empty V53() countable set
({i4} \/ (UsedInt*Loc (SubFrom ((intloc 5),(intloc 6))))) \/ (UsedInt*Loc (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is non empty V53() countable set
{i4} \/ {} is non empty V53() countable set
UsedInt*Loc ((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc ((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) \/ (UsedInt*Loc (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc ((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) \/ {i4} is non empty V53() countable set
UsedInt*Loc (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ (UsedInt*Loc (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is V53() countable Element of K32(FinSeq-Locations)
((UsedInt*Loc (((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) \/ (UsedInt*Loc (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) \/ {i4} is non empty V53() countable set
UsedInt*Loc ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0)))) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5)))))))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0))))) \/ (UsedInt*Loc (Times ((intloc 1),(((((((((intloc 2) :=len i4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (i4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (i4,(intloc 2)))) ";" ((intloc 6) := (i4,(intloc 3)))) ";" ((i4,(intloc 2)) := (intloc 6))) ";" ((i4,(intloc 3)) := (intloc 5))))))))) is V53() countable Element of K32(FinSeq-Locations)
(UsedInt*Loc ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) ";" (SubFrom ((intloc 1),(intloc 0))))) \/ {i4} is non empty V53() countable set
UsedInt*Loc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4)) is V53() countable Element of K32(FinSeq-Locations)
UsedInt*Loc (SubFrom ((intloc 1),(intloc 0))) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ (UsedInt*Loc (SubFrom ((intloc 1),(intloc 0)))) is V53() countable set
((UsedInt*Loc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ (UsedInt*Loc (SubFrom ((intloc 1),(intloc 0))))) \/ {i4} is non empty V53() countable set
(UsedInt*Loc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ {} is V53() countable set
((UsedInt*Loc (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len i4))) \/ {}) \/ {i4} is non empty V53() countable set
UsedInt*Loc ((intloc 1) :=len i4) is V53() countable Element of Fin FinSeq-Locations
(UsedInt*Loc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) \/ (UsedInt*Loc ((intloc 1) :=len i4)) is V53() countable set
((UsedInt*Loc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) \/ (UsedInt*Loc ((intloc 1) :=len i4))) \/ {} is V53() countable set
(((UsedInt*Loc ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) \/ (UsedInt*Loc ((intloc 1) :=len i4))) \/ {}) \/ {i4} is non empty V53() countable set
f0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
f0 ";" b1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
b2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(f0 ";" b1) ";" b2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
b3 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
((f0 ";" b1) ";" b2) ";" b3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
card (((f0 ";" b1) ";" b2) ";" b3) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((f0 ";" b1) ";" b2) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((f0 ";" b1) ";" b2)) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
6 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
f0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
b1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
f0 ";" b1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
b2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(f0 ";" b1) ";" b2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
b3 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
((f0 ";" b1) ";" b2) ";" b3 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
b4 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
(((f0 ";" b1) ";" b2) ";" b3) ";" b4 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
card ((((f0 ";" b1) ";" b2) ";" b3) ";" b4) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (((f0 ";" b1) ";" b2) ";" b3) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (((f0 ";" b1) ";" b2) ";" b3)) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
8 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
82 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
b4 is FinSeq-Location
(b4) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(intloc 1) :=len b4 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 1),b4*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 1),b4*>) is set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4)) ";" (SubFrom ((intloc 1),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 2) :=len b4 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 2),b4*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 2),b4*>) is set
((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := (b4,(intloc 3)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),b4,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 6),b4,(intloc 3)*>) is set
(((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := (b4,(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),b4,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 5),b4,(intloc 2)*>) is set
((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(b4,(intloc 2)) := (intloc 6) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),b4,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 6),b4,(intloc 2)*>) is set
(((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(b4,(intloc 3)) := (intloc 5) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),b4,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 5),b4,(intloc 3)*>) is set
((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Times ((intloc 1),(((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4)) ";" (SubFrom ((intloc 1),(intloc 0)))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
card (b4) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (Macro (SubFrom ((intloc 2),(intloc 2)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (Macro (SubFrom ((intloc 2),(intloc 2))))) + (card ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((card (Macro (SubFrom ((intloc 2),(intloc 2))))) + (card ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
2 + (card ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(2 + (card ((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
2 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
2 + (2 + 2) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(2 + (2 + 2)) + 4 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card ((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))))) + (card (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(2 + 2) + 10 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
14 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card (((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6)))) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
10 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card (((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) + (card (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) + (card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((card (((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))))) + (card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) + (card (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3))))) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((card ((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3))))) + 2) + (card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(((card ((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3))))) + 2) + (card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) + (card (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(10 + 2) + (card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((10 + 2) + (card (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))))) + (card (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
14 + 6 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(10 + 2) + (14 + 6) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((10 + 2) + (14 + 6)) + (card (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
12 + 12 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((10 + 2) + (14 + 6)) + (12 + 12) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
56 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4)) ";" (SubFrom ((intloc 1),(intloc 0)))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (Times ((intloc 1),(((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5)))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4)) ";" (SubFrom ((intloc 1),(intloc 0))))) + (card (Times ((intloc 1),(((((((((intloc 2) :=len b4) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (b4,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (b4,(intloc 2)))) ";" ((intloc 6) := (b4,(intloc 3)))) ";" ((b4,(intloc 2)) := (intloc 6))) ";" ((b4,(intloc 3)) := (intloc 5))))))))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
56 + 12 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(card ((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4)) ";" (SubFrom ((intloc 1),(intloc 0))))) + (56 + 12) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4))) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((card (((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len b4))) + 2) + (56 + 12) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(card ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((card ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) + 2) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(((card ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0)))) + 2) + 2) + (56 + 12) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(10 + 2) + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
68 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((10 + 2) + 2) + 68 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
f0 is FinSeq-Location
(f0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(intloc 1) :=len f0 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 1),f0*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 1),f0*>) is set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len f0) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len f0)) ";" (SubFrom ((intloc 1),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 2) :=len f0 is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 2),f0*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc 2),f0*>) is set
((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 6) := (f0,(intloc 3)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),f0,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 6),f0,(intloc 3)*>) is set
(((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(intloc 5) := (f0,(intloc 2)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),f0,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc 5),f0,(intloc 2)*>) is set
((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(f0,(intloc 2)) := (intloc 6) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 6),f0,(intloc 2)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 6),f0,(intloc 2)*>) is set
(((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
(f0,(intloc 3)) := (intloc 5) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc 5),f0,(intloc 3)*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc 5),f0,(intloc 3)*>) is set
((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
Times ((intloc 1),(((((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
((((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len f0)) ";" (SubFrom ((intloc 1),(intloc 0)))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len f0) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := (f0,(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := (f0,(intloc 2)))) ";" ((intloc 6) := (f0,(intloc 3)))) ";" ((f0,(intloc 2)) := (intloc 6))) ";" ((f0,(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free set
dom (f0) is non empty V53() countable V132() set
b1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (f0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
goto 4 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
goto 6 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
goto 8 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
goto 10 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
goto 12 is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((intloc 3) := (intloc 0)) ";" (((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
Macro ((intloc 2) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
K331(SCM+FSA,((intloc 2) := (intloc 0))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
stop K331(SCM+FSA,((intloc 2) := (intloc 0))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
dom (Macro ((intloc 2) := (intloc 0))) is non empty V53() countable V132() set
{0,1} is non empty V53() countable set
card (((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" ((intloc 1) :=len (fsloc 0))) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" (((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(Macro ((intloc 2) := (intloc 0))) ";" ((intloc 3) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting V161(3, SCM+FSA ) set
((Macro ((intloc 2) := (intloc 0))) ";" ((intloc 3) := (intloc 0))) ";" (((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
((intloc 2) := (intloc 0)) ";" (((intloc 3) := (intloc 0)) ";" (((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
(Macro ((intloc 2) := (intloc 0))) ";" (((intloc 3) := (intloc 0)) ";" (((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5)))))))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
m1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
m1 . 0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 3 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 4 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 5 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 6 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 7 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 8 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 9 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 10 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m1 . 11 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
m2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
dom ((fsloc 0)) is non empty V53() countable V132() set
((fsloc 0)) . m2 is set
m1 . m2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
((Macro ((intloc 2) := (intloc 0))) ";" (((intloc 3) := (intloc 0)) ";" (((intloc 4) := (intloc 0)) ";" (((intloc 5) := (intloc 0)) ";" (((intloc 6) := (intloc 0)) ";" (((intloc 1) :=len (fsloc 0)) ";" ((SubFrom ((intloc 1),(intloc 0))) ";" (Times ((intloc 1),(((((((((intloc 2) :=len (fsloc 0)) ";" (SubFrom ((intloc 2),(intloc 1)))) ";" ((intloc 3) := (intloc 2))) ";" (AddTo ((intloc 3),(intloc 0)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (SubFrom ((intloc 4),(intloc 4)))) ";" (while>0 ((intloc 2),((((intloc 5) := ((fsloc 0),(intloc 2))) ";" (SubFrom ((intloc 5),(intloc 6)))) ";" (if>0 ((intloc 5),(Macro (SubFrom ((intloc 2),(intloc 2)))),((AddTo ((intloc 4),(intloc 0))) ";" (SubFrom ((intloc 2),(intloc 0)))))))))) ";" (Times ((intloc 4),(((((((intloc 2) := (intloc 3)) ";" (SubFrom ((intloc 3),(intloc 0)))) ";" ((intloc 5) := ((fsloc 0),(intloc 2)))) ";" ((intloc 6) := ((fsloc 0),(intloc 3)))) ";" (((fsloc 0),(intloc 2)) := (intloc 6))) ";" (((fsloc 0),(intloc 3)) := (intloc 5))))))))))))))) . 0 is set
Directed (Macro ((intloc 2) := (intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() halt-free V105( SCM+FSA ) set
(Directed (Macro ((intloc 2) := (intloc 0)))) . 0 is set
card (Macro ((intloc 2) := (intloc 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card ((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
card (((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
6 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
card ((((((intloc 2) := (intloc 0)) ";" ((intloc 3) := (intloc 0))) ";" ((intloc 4) := (intloc 0))) ";" ((intloc 5) := (intloc 0))) ";" ((intloc 6) := (intloc 0))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
8 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((fsloc 0)) . 1 is set
(Directed (Macro ((intloc 2) := (intloc 0)))) . 1 is set
((fsloc 0)) . 2 is set
2 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((fsloc 0)) . (2 + 1) is set
2 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
goto (2 + 2) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((fsloc 0)) . 4 is set
4 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((fsloc 0)) . (4 + 1) is set
4 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
goto (4 + 2) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((fsloc 0)) . 6 is set
6 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((fsloc 0)) . (6 + 1) is set
goto (6 + 2) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((fsloc 0)) . 8 is set
8 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((fsloc 0)) . (8 + 1) is set
goto (8 + 2) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((fsloc 0)) . 10 is set
10 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((fsloc 0)) . (10 + 1) is set
10 + 2 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
goto (10 + 2) is non ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
intloc (0 + 1) is V111() non read-only Element of the carrier of SCM+FSA
1 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
intloc (1 + 1) is V111() non read-only Element of the carrier of SCM+FSA
2 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
intloc (2 + 1) is V111() non read-only Element of the carrier of SCM+FSA
3 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
intloc (3 + 1) is V111() non read-only Element of the carrier of SCM+FSA
4 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
intloc (4 + 1) is V111() non read-only Element of the carrier of SCM+FSA
5 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
intloc (5 + 1) is V111() non read-only Element of the carrier of SCM+FSA
(intloc (1 + 1)) := (intloc (2 + 1)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
SubFrom ((intloc (2 + 1)),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc (4 + 1)),(fsloc 0),(intloc (1 + 1))*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc (4 + 1)),(fsloc 0),(intloc (1 + 1))*>) is set
(intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc (5 + 1)),(fsloc 0),(intloc (2 + 1))*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(9,{},<*(intloc (5 + 1)),(fsloc 0),(intloc (2 + 1))*>) is set
((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc (5 + 1)),(fsloc 0),(intloc (1 + 1))*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc (5 + 1)),(fsloc 0),(intloc (1 + 1))*>) is set
((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc (4 + 1)),(fsloc 0),(intloc (2 + 1))*> is non empty Relation-like NAT -defined Function-like V53() 3 -element countable FinSequence-like FinSubsequence-like set
K15(10,{},<*(intloc (4 + 1)),(fsloc 0),(intloc (2 + 1))*>) is set
((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(intloc (1 + 1)) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc (2 + 1)) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc (3 + 1)) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc (4 + 1)) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc (5 + 1)) := (intloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free good set
SubFrom ((intloc (1 + 1)),(intloc (1 + 1))) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
K331(SCM+FSA,(SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
stop K331(SCM+FSA,(SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))) is Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable set
AddTo ((intloc (3 + 1)),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
SubFrom ((intloc (1 + 1)),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
SubFrom ((intloc (4 + 1)),(intloc (5 + 1))) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
(intloc (1 + 1)) :=len (fsloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc (1 + 1)),(fsloc 0)*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc (1 + 1)),(fsloc 0)*>) is set
SubFrom ((intloc (1 + 1)),(intloc (0 + 1))) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
(intloc (2 + 1)) := (intloc (1 + 1)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
AddTo ((intloc (2 + 1)),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
SubFrom ((intloc (3 + 1)),(intloc (3 + 1))) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free good set
(intloc (0 + 1)) :=len (fsloc 0) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V156(3, SCM+FSA ) V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
<*(intloc (0 + 1)),(fsloc 0)*> is non empty Relation-like NAT -defined Function-like V53() 2 -element countable FinSequence-like FinSubsequence-like set
K15(11,{},<*(intloc (0 + 1)),(fsloc 0)*>) is set
SubFrom ((intloc (0 + 1)),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 . (intloc 0) is ext-real V36() V37() integer set
T1 . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (T1 . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput (q,T1,11) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,11)) . (intloc 1) is ext-real V36() V37() integer set
(Comput (q,T1,11)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,11)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,11)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,11)) . (intloc 5) is ext-real V36() V37() integer set
(Comput (q,T1,11)) . (intloc 6) is ext-real V36() V37() integer set
Comput (q,T1,0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (q,T1,0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (q,T1,0)) . (IC ) is set
Comput (q,T1,(0 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 0 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 0),(Comput (q,T1,0))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (q . 0) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 0)) . (Comput (q,T1,0)) is set
Exec (((intloc 2) := (intloc 0)),(Comput (q,T1,0))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc 2) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc 2) := (intloc 0))) . (Comput (q,T1,0)) is set
Comput (q,T1,1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,1)) . (IC ) is set
succ (IC (Comput (q,T1,0))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
IC (Comput (q,T1,1)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (q,T1,(1 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 1 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 1),(Comput (q,T1,1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 1) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 1)) . (Comput (q,T1,1)) is set
Exec ((goto 2),(Comput (q,T1,1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 2) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 2)) . (Comput (q,T1,1)) is set
Comput (q,T1,2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,2)) . (IC ) is set
IC (Comput (q,T1,2)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (q,T1,(2 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 2 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 2),(Comput (q,T1,2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 2) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 2)) . (Comput (q,T1,2)) is set
Exec (((intloc 3) := (intloc 0)),(Comput (q,T1,2))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc 3) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc 3) := (intloc 0))) . (Comput (q,T1,2)) is set
Comput (q,T1,3) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,3)) . (IC ) is set
succ (IC (Comput (q,T1,2))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
IC (Comput (q,T1,3)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (q,T1,(3 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 3 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 3),(Comput (q,T1,3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 3) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 3)) . (Comput (q,T1,3)) is set
Exec ((goto 4),(Comput (q,T1,3))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 4) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 4)) . (Comput (q,T1,3)) is set
Comput (q,T1,4) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,4)) . (IC ) is set
(Comput (q,T1,1)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,2)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,3)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,4)) . (intloc 3) is ext-real V36() V37() integer set
IC (Comput (q,T1,4)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (q,T1,(4 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 4 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 4),(Comput (q,T1,4))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 4) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 4)) . (Comput (q,T1,4)) is set
Exec (((intloc 4) := (intloc 0)),(Comput (q,T1,4))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc 4) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc 4) := (intloc 0))) . (Comput (q,T1,4)) is set
Comput (q,T1,5) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,5)) . (IC ) is set
succ (IC (Comput (q,T1,4))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
IC (Comput (q,T1,5)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (q,T1,(5 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 5 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 5),(Comput (q,T1,5))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 5) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 5)) . (Comput (q,T1,5)) is set
Exec ((goto 6),(Comput (q,T1,5))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 6) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 6)) . (Comput (q,T1,5)) is set
Comput (q,T1,6) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,6)) . (IC ) is set
IC (Comput (q,T1,6)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
6 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput (q,T1,(6 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 6 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 6),(Comput (q,T1,6))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 6) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 6)) . (Comput (q,T1,6)) is set
Exec (((intloc 5) := (intloc 0)),(Comput (q,T1,6))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc 5) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc 5) := (intloc 0))) . (Comput (q,T1,6)) is set
Comput (q,T1,7) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,7)) . (IC ) is set
succ (IC (Comput (q,T1,6))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
IC (Comput (q,T1,7)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
7 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput (q,T1,(7 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 7 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 7),(Comput (q,T1,7))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 7) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 7)) . (Comput (q,T1,7)) is set
Exec ((goto 8),(Comput (q,T1,7))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 8) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 8)) . (Comput (q,T1,7)) is set
Comput (q,T1,8) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,8)) . (IC ) is set
IC (Comput (q,T1,8)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
8 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput (q,T1,(8 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 8 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 8),(Comput (q,T1,8))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 8) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 8)) . (Comput (q,T1,8)) is set
Exec (((intloc 6) := (intloc 0)),(Comput (q,T1,8))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc 6) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc 6) := (intloc 0))) . (Comput (q,T1,8)) is set
Comput (q,T1,9) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,9)) . (IC ) is set
succ (IC (Comput (q,T1,8))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
IC (Comput (q,T1,9)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
9 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput (q,T1,(9 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 9 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 9),(Comput (q,T1,9))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 9) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 9)) . (Comput (q,T1,9)) is set
Exec ((goto 10),(Comput (q,T1,9))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (goto 10) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (goto 10)) . (Comput (q,T1,9)) is set
Comput (q,T1,10) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,10)) . (IC ) is set
(Comput (q,T1,1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,2)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,3)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,4)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,5)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,6)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,7)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,8)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,9)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,10)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (q,T1,3)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,4)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,5)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,6)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,5)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,6)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,7)) . (intloc 5) is ext-real V36() V37() integer set
(Comput (q,T1,8)) . (intloc 5) is ext-real V36() V37() integer set
(Comput (q,T1,7)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,8)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,9)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,10)) . (intloc 4) is ext-real V36() V37() integer set
(Comput (q,T1,9)) . (intloc 5) is ext-real V36() V37() integer set
(Comput (q,T1,10)) . (intloc 5) is ext-real V36() V37() integer set
(Comput (q,T1,7)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,8)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,9)) . (intloc 6) is ext-real V36() V37() integer set
(Comput (q,T1,10)) . (intloc 6) is ext-real V36() V37() integer set
IC (Comput (q,T1,10)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
10 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
Comput (q,T1,(10 + 1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . 10 is with_explicit_jumps IC-relocable Element of the InstructionsF of SCM+FSA
Exec ((q . 10),(Comput (q,T1,10))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (q . 10) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (q . 10)) . (Comput (q,T1,10)) is set
Exec (((intloc 1) :=len (fsloc 0)),(Comput (q,T1,10))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc 1) :=len (fsloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc 1) :=len (fsloc 0))) . (Comput (q,T1,10)) is set
(Comput (q,T1,11)) . (IC ) is set
succ (IC (Comput (q,T1,10))) is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() set
(Comput (q,T1,9)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,10)) . (intloc 0) is ext-real V36() V37() integer set
p is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (q,T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (q,T1,p)) . (IC ) is set
(Comput (q,T1,p)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (q,T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
11 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(Comput (q,T1,1)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,2)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,3)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,4)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,5)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,6)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,7)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,8)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,9)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,10)) . (intloc 2) is ext-real V36() V37() integer set
(Comput (q,T1,5)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,6)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,7)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,8)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,9)) . (intloc 3) is ext-real V36() V37() integer set
(Comput (q,T1,10)) . (intloc 3) is ext-real V36() V37() integer set
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,q)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
q . (intloc (1 + 1)) is ext-real V36() V37() integer set
(q . (intloc (1 + 1))) - 1 is ext-real V36() V37() integer set
Initialized q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
q +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0)))) . (Initialized q) is set
IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,q)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))) . (Initialized q) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized q))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Initialized q) . (intloc (1 + 1)) is ext-real V36() V37() integer set
((Initialized q) . (intloc (1 + 1))) - ((Initialized q) . (intloc (1 + 1))) is ext-real V36() V37() integer set
(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) . (intloc 0) is ext-real V36() V37() integer set
(Initialized q) . (intloc 0) is ext-real V36() V37() integer set
IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,q)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0)))) . (Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
T1 . (intloc (1 + 1)) is ext-real V36() V37() integer set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Initialized T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) . (Initialized T1) is set
IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) . (Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) is set
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Initialized T1) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(T1 . (intloc (1 + 1))) - 1 is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q +* (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like total non halt-free set
Initialize T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
dom ((intloc 0) .--> 1) is V5() V53() countable set
{(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
dom (Start-At (0,SCM+FSA)) is non empty V53() countable set
(dom ((intloc 0) .--> 1)) \/ (dom (Start-At (0,SCM+FSA))) is non empty V53() countable set
T1 . (intloc 0) is ext-real V36() V37() integer set
(Initialize ((intloc 0) .--> 1)) . (intloc 0) is set
((intloc 0) .--> 1) . (intloc 0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V126() set
p is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
p ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
(p ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
x is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
x ";" q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
(x ";" q) ";" T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() non halt-free good set
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q +* (Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued the InstructionsF of SCM+FSA -valued Function-like total non halt-free set
Initialize T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 +* (Start-At (0,SCM+FSA)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
dom ((intloc 0) .--> 1) is V5() V53() countable set
{(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
dom (Start-At (0,SCM+FSA)) is non empty V53() countable set
(dom ((intloc 0) .--> 1)) \/ (dom (Start-At (0,SCM+FSA))) is non empty V53() countable set
T1 . (intloc 0) is ext-real V36() V37() integer set
(Initialize ((intloc 0) .--> 1)) . (intloc 0) is set
((intloc 0) .--> 1) . (intloc 0) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V126() set
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
q . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Initialized q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
q +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
q . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))) . (Initialized q) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized q))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Initialized q) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
q . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0)))) . (Initialized q) is set
Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0)))) . (Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Initialized q) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
q . (intloc (4 + 1)) is ext-real V36() V37() integer set
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,q)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
q . (intloc (3 + 1)) is ext-real V36() V37() integer set
(q . (intloc (3 + 1))) + 1 is ext-real V36() V37() integer set
Initialized q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
q +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,q)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))) . (Initialized q) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized q))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Initialized q) . (intloc (3 + 1)) is ext-real V36() V37() integer set
IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,q)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0)))) . (Initialized q) is set
Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0)))) . (Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized q))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Initialized q) . (intloc 0) is ext-real V36() V37() integer set
((Initialized q) . (intloc (3 + 1))) + ((Initialized q) . (intloc 0)) is ext-real V36() V37() integer set
((Initialized q) . (intloc (3 + 1))) + 1 is ext-real V36() V37() integer set
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q is V111() non read-only Element of the carrier of SCM+FSA
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),T1,p)) . q is ext-real V36() V37() integer set
p . q is ext-real V36() V37() integer set
Initialized p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
p +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized p)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (AddTo ((intloc (3 + 1)),(intloc 0)))) . (Initialized p) is set
IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized p))) . q is ext-real V36() V37() integer set
(Initialized p) . q is ext-real V36() V37() integer set
(IExec (((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))),T1,p)) . q is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized p)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc 0)))) . (Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized p))) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc 0))),(Exec ((AddTo ((intloc (3 + 1)),(intloc 0))),(Initialized p))))) . q is ext-real V36() V37() integer set
p . (intloc (4 + 1)) is ext-real V36() V37() integer set
IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),T1,p)) . q is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized p)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))) . (Initialized p) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc (1 + 1)))),(Initialized p))) . q is ext-real V36() V37() integer set
p . (intloc (4 + 1)) is ext-real V36() V37() integer set
p . (intloc (4 + 1)) is ext-real V36() V37() integer set
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
T1 . (intloc (1 + 1)) is ext-real V36() V37() integer set
T1 . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (T1 . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
T1 . (intloc (2 + 1)) is ext-real V36() V37() integer set
T1 . (intloc (5 + 1)) is ext-real V36() V37() integer set
(T1 . (fsloc 0)) . (T1 . (intloc (1 + 1))) is ext-real V36() V37() integer set
T1 . (intloc (3 + 1)) is ext-real V36() V37() integer set
(T1 . (intloc (1 + 1))) - 1 is ext-real V36() V37() integer set
(T1 . (intloc (3 + 1))) + 1 is ext-real V36() V37() integer set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),q,T1)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
abs (T1 . (intloc (1 + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Initialized T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) . (Initialized T1) is set
IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
d is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(T1 . (fsloc 0)) . d is ext-real V36() V37() integer set
(T1 . (fsloc 0)) /. d is ext-real V36() V37() integer Element of INT
t is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(Initialized T1) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Initialized T1) . (intloc (1 + 1)) is ext-real V36() V37() integer set
abs ((Initialized T1) . (intloc (1 + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((Initialized T1) . (fsloc 0)) /. (abs ((Initialized T1) . (intloc (1 + 1)))) is ext-real V36() V37() integer Element of INT
((Initialized T1) . (fsloc 0)) /. (abs (T1 . (intloc (1 + 1)))) is ext-real V36() V37() integer Element of INT
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(Initialized T1) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) . (Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) is set
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (intloc (4 + 1)) is ext-real V36() V37() integer set
t - (T1 . (intloc (5 + 1))) is ext-real V36() V37() integer set
IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Initialized T1) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Initialized T1) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec ((if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))),q,(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (4 + 1)),(intloc (5 + 1)))),(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(Initialized T1))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
q + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p . (intloc (1 + 1)) is ext-real V36() V37() integer set
p . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (p . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Initialized (IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
1 + 0 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(p . (fsloc 0)) . (p . (intloc (1 + 1))) is ext-real V36() V37() integer set
p . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
p . (intloc (3 + 1)) is ext-real V36() V37() integer set
(p . (intloc (1 + 1))) - 1 is ext-real V36() V37() integer set
(p . (intloc (3 + 1))) + 1 is ext-real V36() V37() integer set
d is ext-real V36() V37() integer set
d - (p . (intloc (5 + 1))) is ext-real V36() V37() integer set
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
t is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Initialized (IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
p . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Initialized (IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
P is empty Relation-like non-empty empty-yielding NAT -defined RAT -valued Function-like one-to-one constant functional ext-real non positive non negative epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V36() V37() V38() V39() V40() V41() integer V53() V54() V57() Cardinal-yielding countable FinSequence-like FinSubsequence-like FinSequence-membered Function-yielding V151() Element of NAT
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
(q + 1) - P is non empty ext-real positive non negative V36() V37() integer set
u is ext-real V36() V37() integer set
(p . (fsloc 0)) . ((q + 1) - P) is ext-real V36() V37() integer set
0 + (p . (intloc (5 + 1))) is ext-real V36() V37() integer set
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
z is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(p . (fsloc 0)) . z is ext-real V36() V37() integer set
P is empty Relation-like non-empty empty-yielding NAT -defined RAT -valued Function-like one-to-one constant functional ext-real non positive non negative epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V36() V37() V38() V39() V40() V41() integer V53() V54() V57() Cardinal-yielding countable FinSequence-like FinSubsequence-like FinSequence-membered Function-yielding V151() Element of NAT
(q + 1) - P is non empty ext-real positive non negative V36() V37() integer set
u is ext-real V36() V37() integer set
(p . (fsloc 0)) . ((q + 1) - P) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
t is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (t,T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
p . (intloc (2 + 1)) is ext-real V36() V37() integer set
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (intloc (3 + 1))) - ((IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (intloc (3 + 1))) is ext-real V36() V37() integer set
(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
q - P is ext-real V36() V37() integer set
u is ext-real V36() V37() integer set
((IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (fsloc 0)) . (q - P) is ext-real V36() V37() integer set
IExec (t,T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (t,T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
1 + P is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(p . (intloc (3 + 1))) + (1 + P) is ext-real V36() V37() integer set
z is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
(q + 1) - z is ext-real V36() V37() integer set
bf is ext-real V36() V37() integer set
(p . (fsloc 0)) . ((q + 1) - z) is ext-real V36() V37() integer set
s2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
i is ext-real V36() V37() integer set
(p . (fsloc 0)) . s2 is ext-real V36() V37() integer set
0 + (p . (intloc (5 + 1))) is ext-real V36() V37() integer set
((IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)) . (fsloc 0)) . s2 is ext-real V36() V37() integer set
i is ext-real V36() V37() integer set
Cs1i is ext-real V36() V37() integer set
(p . (fsloc 0)) . s2 is ext-real V36() V37() integer set
s2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(p . (fsloc 0)) . s2 is ext-real V36() V37() integer set
z is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(q + 1) - z is ext-real V36() V37() integer set
bf is ext-real V36() V37() integer set
(p . (fsloc 0)) . ((q + 1) - z) is ext-real V36() V37() integer set
IExec (t,T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (t,T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,(IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(Initialized (IExec (((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))),T1,p))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
P is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
(q + 1) - P is ext-real V36() V37() integer set
u is empty Relation-like non-empty empty-yielding NAT -defined RAT -valued Function-like one-to-one constant functional ext-real non positive non negative epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V36() V37() V38() V39() V40() V41() integer V53() V54() V57() Cardinal-yielding countable FinSequence-like FinSubsequence-like FinSequence-membered Function-yielding V151() Element of NAT
(p . (fsloc 0)) . ((q + 1) - P) is ext-real V36() V37() integer set
z is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
bf is ext-real V36() V37() integer set
(p . (fsloc 0)) . z is ext-real V36() V37() integer set
0 + (p . (intloc (5 + 1))) is ext-real V36() V37() integer set
P is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(q + 1) - P is ext-real V36() V37() integer set
u is empty Relation-like non-empty empty-yielding NAT -defined RAT -valued Function-like one-to-one constant functional ext-real non positive non negative epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V36() V37() V38() V39() V40() V41() integer V53() V54() V57() Cardinal-yielding countable FinSequence-like FinSubsequence-like FinSequence-membered Function-yielding V151() Element of NAT
(p . (fsloc 0)) . ((q + 1) - P) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p . (intloc (1 + 1)) is ext-real V36() V37() integer set
p . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (p . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
p . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
p . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
p . (intloc (5 + 1)) is ext-real V36() V37() integer set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . (intloc (1 + 1)) is ext-real V36() V37() integer set
q . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (q . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
q . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,q)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
q . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,q)) . (intloc (3 + 1))) - (q . (intloc (3 + 1))) is ext-real V36() V37() integer set
q . (intloc (5 + 1)) is ext-real V36() V37() integer set
Initialized q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
q +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized q) . (intloc (2 + 1)) is ext-real V36() V37() integer set
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p . (intloc (1 + 1)) is ext-real V36() V37() integer set
q is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
p . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (p . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
p . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
p . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),T1,p)) . (intloc (3 + 1))) - (p . (intloc (3 + 1))) is ext-real V36() V37() integer set
p . (intloc (5 + 1)) is ext-real V36() V37() integer set
q + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
T1 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),T1,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
q . (intloc (2 + 1)) is ext-real V36() V37() integer set
(q . (intloc (2 + 1))) - 1 is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
q . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
abs (q . (intloc (2 + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
abs ((q . (intloc (2 + 1))) - 1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(q . (fsloc 0)) /. (abs ((q . (intloc (2 + 1))) - 1)) is ext-real V36() V37() integer Element of INT
(q . (fsloc 0)) +* ((abs (q . (intloc (2 + 1)))),((q . (fsloc 0)) /. (abs ((q . (intloc (2 + 1))) - 1)))) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(q . (fsloc 0)) /. (abs (q . (intloc (2 + 1)))) is ext-real V36() V37() integer Element of INT
((q . (fsloc 0)) +* ((abs (q . (intloc (2 + 1)))),((q . (fsloc 0)) /. (abs ((q . (intloc (2 + 1))) - 1))))) +* ((abs ((q . (intloc (2 + 1))) - 1)),((q . (fsloc 0)) /. (abs (q . (intloc (2 + 1)))))) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Initialized q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
q +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . ((intloc (1 + 1)) := (intloc (2 + 1))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (1 + 1)) := (intloc (2 + 1)))) . (Initialized q) is set
IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (intloc 0) is ext-real V36() V37() integer set
(Initialized q) . (intloc 0) is ext-real V36() V37() integer set
(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (2 + 1)),(intloc 0))),(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (2 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (2 + 1)),(intloc 0)))) . (Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) is set
(Exec ((SubFrom ((intloc (2 + 1)),(intloc 0))),(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Initialized q) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) . (IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)) is set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) . (IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)) is set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (2 + 1)),(intloc 0))),(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
((Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (intloc (2 + 1))) - ((Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (intloc 0)) is ext-real V36() V37() integer set
((Initialized q) . (intloc (2 + 1))) - ((Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (intloc 0)) is ext-real V36() V37() integer set
(IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
Exec ((((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1))),(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) . (IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)) is set
(Exec ((((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1))),(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
Exec ((((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))),(IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) . (IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q)) is set
(Exec ((((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))),(IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((SubFrom ((intloc (2 + 1)),(intloc 0))),(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (1 + 1)) := (intloc (2 + 1))),(Initialized q))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Initialized q) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)))) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1))),(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(Exec ((((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1))),(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)))) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(IExec ((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),T1,q)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)))) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))),T1,q)) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))),(IExec ((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))),T1,q)))) . (intloc (4 + 1)) is ext-real V36() V37() integer set
(Exec ((((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))),(IExec (((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))),T1,q)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
SubFrom ((intloc (3 + 1)),(intloc 0)) is ins-loc-free V101( the InstructionsF of SCM+FSA) V107(3, SCM+FSA ) parahalting keeping_0 good with_explicit_jumps IC-relocable V158(3, SCM+FSA ) Element of the InstructionsF of SCM+FSA
q is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p . (intloc (3 + 1)) is ext-real V36() V37() integer set
q + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
p . (intloc (2 + 1)) is ext-real V36() V37() integer set
p . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (p . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(p . (intloc (2 + 1))) - 1 is ext-real V36() V37() integer set
(q + 1) - 1 is ext-real V36() V37() integer set
w is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
x is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (3 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (SubFrom ((intloc (3 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (3 + 1)),(intloc 0)))) . (IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) is set
(Exec ((SubFrom ((intloc (3 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (intloc 0) is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (intloc (3 + 1))) - ((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (intloc 0)) is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (intloc (3 + 1))) - 1 is ext-real V36() V37() integer set
Initialized p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
p +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized p) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((Initialized p) . (intloc (3 + 1))) - 1 is ext-real V36() V37() integer set
z is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
abs (p . (intloc (2 + 1))) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(q + 1) + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((q + 1) + 1) - 1 is ext-real V36() V37() integer set
IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (3 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
((IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (intloc (2 + 1))) - q is ext-real V36() V37() integer set
(p . (intloc (2 + 1))) - (q + 1) is ext-real V36() V37() integer set
abs ((p . (intloc (2 + 1))) - 1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(p . (fsloc 0)) /. w is ext-real V36() V37() integer Element of INT
(p . (fsloc 0)) +* (z,((p . (fsloc 0)) /. w)) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(p . (fsloc 0)) /. z is ext-real V36() V37() integer Element of INT
((p . (fsloc 0)) +* (z,((p . (fsloc 0)) /. w))) +* (w,((p . (fsloc 0)) /. z)) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(p . (fsloc 0)) . z is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (fsloc 0)) . w is ext-real V36() V37() integer set
(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((SubFrom ((intloc (3 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len ((IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (fsloc 0)) . (((IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (intloc (2 + 1))) - q) is ext-real V36() V37() integer set
((IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (fsloc 0)) . ((IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)) . (intloc (2 + 1))) is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . ((p . (intloc (2 + 1))) - (q + 1)) is ext-real V36() V37() integer set
(p . (fsloc 0)) . (p . (intloc (2 + 1))) is ext-real V36() V37() integer set
(p . (fsloc 0)) . w is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (fsloc 0)) . z is ext-real V36() V37() integer set
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (fsloc 0)) . bf is ext-real V36() V37() integer set
bf - 1 is ext-real V36() V37() integer set
(p . (fsloc 0)) . (bf - 1) is ext-real V36() V37() integer set
bf + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
((p . (intloc (2 + 1))) - (q + 1)) + 1 is ext-real V36() V37() integer set
(((p . (intloc (2 + 1))) - (q + 1)) + 1) - 1 is ext-real V36() V37() integer set
bf - 1 is ext-real V36() V37() integer set
(q + 1) - (q + 1) is ext-real V36() V37() integer set
s2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
1 + 0 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
dom (p . (fsloc 0)) is V53() countable V132() Element of K32(NAT)
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (fsloc 0)) . (bf - 1) is ext-real V36() V37() integer set
(p . (fsloc 0)) . (bf - 1) is ext-real V36() V37() integer set
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
dom (p . (fsloc 0)) is V53() countable V132() Element of K32(NAT)
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
(p . (fsloc 0)) . bf is ext-real V36() V37() integer set
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((p . (intloc (2 + 1))) - 1) - q is ext-real V36() V37() integer set
((p . (intloc (2 + 1))) - 1) - 0 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,(IExec (((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))) ";" (SubFrom ((intloc (3 + 1)),(intloc 0)))),x,p)))) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))),x,p)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
(p . (fsloc 0)) . bf is ext-real V36() V37() integer set
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p . (intloc (3 + 1)) is ext-real V36() V37() integer set
p . (intloc (2 + 1)) is ext-real V36() V37() integer set
p . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (p . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
x is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(p . (intloc (2 + 1))) - (q + 1) is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . ((p . (intloc (2 + 1))) - (q + 1)) is ext-real V36() V37() integer set
(p . (fsloc 0)) . (p . (intloc (2 + 1))) is ext-real V36() V37() integer set
w is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . w is ext-real V36() V37() integer set
w - 1 is ext-real V36() V37() integer set
(p . (fsloc 0)) . (w - 1) is ext-real V36() V37() integer set
d is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . d is ext-real V36() V37() integer set
(p . (fsloc 0)) . d is ext-real V36() V37() integer set
t is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),x,p)) . (fsloc 0)) . t is ext-real V36() V37() integer set
(p . (fsloc 0)) . t is ext-real V36() V37() integer set
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
T1 . (intloc (3 + 1)) is ext-real V36() V37() integer set
T1 . (intloc (2 + 1)) is ext-real V36() V37() integer set
T1 . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (T1 . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(T1 . (intloc (2 + 1))) - 0 is ext-real V36() V37() integer set
(T1 . (fsloc 0)) . (T1 . (intloc (2 + 1))) is ext-real V36() V37() integer set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1)) . (fsloc 0)) . ((T1 . (intloc (2 + 1))) - 0) is ext-real V36() V37() integer set
Initialized T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
(Initialized T1) . (intloc (2 + 1)) is ext-real V36() V37() integer set
p is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1)) . (fsloc 0)) . p is ext-real V36() V37() integer set
p - 1 is ext-real V36() V37() integer set
(T1 . (fsloc 0)) . (p - 1) is ext-real V36() V37() integer set
p is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1)) . (fsloc 0)) . p is ext-real V36() V37() integer set
(T1 . (fsloc 0)) . p is ext-real V36() V37() integer set
p is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),q,T1)) . (fsloc 0)) . p is ext-real V36() V37() integer set
(T1 . (fsloc 0)) . p is ext-real V36() V37() integer set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
q . (intloc (3 + 1)) is ext-real V36() V37() integer set
T1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
q . (intloc (2 + 1)) is ext-real V36() V37() integer set
q . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (q . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
p is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(q . (intloc (2 + 1))) - T1 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q)) . (fsloc 0)) . ((q . (intloc (2 + 1))) - T1) is ext-real V36() V37() integer set
(q . (fsloc 0)) . (q . (intloc (2 + 1))) is ext-real V36() V37() integer set
x is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q)) . (fsloc 0)) . x is ext-real V36() V37() integer set
x - 1 is ext-real V36() V37() integer set
(q . (fsloc 0)) . (x - 1) is ext-real V36() V37() integer set
w is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q)) . (fsloc 0)) . w is ext-real V36() V37() integer set
(q . (fsloc 0)) . w is ext-real V36() V37() integer set
d is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),p,q)) . (fsloc 0)) . d is ext-real V36() V37() integer set
(q . (fsloc 0)) . d is ext-real V36() V37() integer set
T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
T1 . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (T1 . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
T1 . (intloc (0 + 1)) is ext-real V36() V37() integer set
(len (T1 . (fsloc 0))) - (T1 . (intloc (0 + 1))) is ext-real V36() V37() integer set
((len (T1 . (fsloc 0))) - (T1 . (intloc (0 + 1)))) + 1 is ext-real V36() V37() integer set
abs (((len (T1 . (fsloc 0))) - (T1 . (intloc (0 + 1)))) + 1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(T1 . (fsloc 0)) /. (abs (((len (T1 . (fsloc 0))) - (T1 . (intloc (0 + 1)))) + 1)) is ext-real V36() V37() integer Element of INT
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))),q,T1)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))),q,T1)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
Initialized T1 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
T1 +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . ((intloc (1 + 1)) :=len (fsloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (1 + 1)) :=len (fsloc 0))) . (Initialized T1) is set
IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (1 + 1)),(intloc (0 + 1)))),(Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (0 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) . (Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) is set
(Exec ((SubFrom ((intloc (1 + 1)),(intloc (0 + 1)))),(Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) . (intloc (0 + 1)) is ext-real V36() V37() integer set
((Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) . (intloc (1 + 1))) - ((Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) . (intloc (0 + 1))) is ext-real V36() V37() integer set
(Initialized T1) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len ((Initialized T1) . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len ((Initialized T1) . (fsloc 0))) - ((Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) . (intloc (0 + 1))) is ext-real V36() V37() integer set
(Initialized T1) . (intloc (0 + 1)) is ext-real V36() V37() integer set
(len ((Initialized T1) . (fsloc 0))) - ((Initialized T1) . (intloc (0 + 1))) is ext-real V36() V37() integer set
(len (T1 . (fsloc 0))) - ((Initialized T1) . (intloc (0 + 1))) is ext-real V36() V37() integer set
Exec ((SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))),(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) . (IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) is set
(Exec ((SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))),(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) . (IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)) is set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec ((AddTo ((intloc (2 + 1)),(intloc 0))),(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (AddTo ((intloc (2 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (AddTo ((intloc (2 + 1)),(intloc 0)))) . (IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)) is set
(Exec ((AddTo ((intloc (2 + 1)),(intloc 0))),(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
Exec (((intloc (2 + 1)) := (intloc (1 + 1))),(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (2 + 1)) := (intloc (1 + 1))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (2 + 1)) := (intloc (1 + 1)))) . (IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)) is set
(Exec (((intloc (2 + 1)) := (intloc (1 + 1))),(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)))) . (intloc (1 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)) . (intloc 0) is ext-real V36() V37() integer set
(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec ((AddTo ((intloc (2 + 1)),(intloc 0))),(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
((IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)) . (intloc (2 + 1))) + 1 is ext-real V36() V37() integer set
(Exec (((intloc (2 + 1)) := (intloc (1 + 1))),(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
((Exec (((intloc (2 + 1)) := (intloc (1 + 1))),(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)))) . (intloc (2 + 1))) + 1 is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))),(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((AddTo ((intloc (2 + 1)),(intloc 0))),(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (2 + 1)) := (intloc (1 + 1))),(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((SubFrom ((intloc (1 + 1)),(intloc (0 + 1)))),(Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (1 + 1)) :=len (fsloc 0)),(Initialized T1))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))),(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec ((SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))),(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (intloc (3 + 1))) - ((IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (intloc (3 + 1))) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))),(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)))) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(IExec (((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))),q,T1)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))),(IExec ((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))),q,T1)))) . (intloc (5 + 1)) is ext-real V36() V37() integer set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
q ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
(q ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1)))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
w is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w . (intloc (0 + 1)) is ext-real V36() V37() integer set
w . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (w . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len (w . (fsloc 0))) - 1 is ext-real V36() V37() integer set
d is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
p is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
x is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
p ";" x is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() InitClosed InitHalting keepInt0_1 good set
t is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
t is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0)) . t is ext-real V36() V37() integer set
z is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0)) . P is ext-real V36() V37() integer set
1 - 1 is ext-real V36() V37() integer set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
u . (intloc (0 + 1)) is ext-real V36() V37() integer set
P + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
u . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (u . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len (u . (fsloc 0))) - 1 is ext-real V36() V37() integer set
(len (u . (fsloc 0))) + (u . (intloc (0 + 1))) is ext-real V36() V37() integer set
((len (u . (fsloc 0))) + (u . (intloc (0 + 1)))) - (u . (intloc (0 + 1))) is ext-real V36() V37() integer set
(len (u . (fsloc 0))) - (u . (intloc (0 + 1))) is ext-real V36() V37() integer set
((len (u . (fsloc 0))) - (u . (intloc (0 + 1)))) + 1 is ext-real V36() V37() integer set
- ((len (u . (fsloc 0))) - 1) is ext-real V36() V37() integer set
- (u . (intloc (0 + 1))) is ext-real V36() V37() integer set
(len (u . (fsloc 0))) + (- ((len (u . (fsloc 0))) - 1)) is ext-real V36() V37() integer set
(len (u . (fsloc 0))) + (- (u . (intloc (0 + 1)))) is ext-real V36() V37() integer set
p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
z is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (p,z,u) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() good set
IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (p,z,u)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (p,z,u)) . (intloc (1 + 1)) is ext-real V36() V37() integer set
len ((IExec (p,z,u)) . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),z,(IExec (p,z,u))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),z,(IExec (p,z,u)))) . (intloc (3 + 1)) is ext-real V36() V37() integer set
(IExec (p,z,u)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
((IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),z,(IExec (p,z,u)))) . (intloc (3 + 1))) - ((IExec (p,z,u)) . (intloc (3 + 1))) is ext-real V36() V37() integer set
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(IExec (p,z,u)) . (intloc (5 + 1)) is ext-real V36() V37() integer set
bf + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
x is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
bf - x is ext-real V36() V37() integer set
x1 is ext-real V36() V37() integer set
((IExec (p,z,u)) . (fsloc 0)) . (bf - x) is ext-real V36() V37() integer set
(bf + 1) - x is ext-real V36() V37() integer set
x - x is ext-real V36() V37() integer set
(u . (fsloc 0)) . (bf + 1) is ext-real V36() V37() integer set
1 + 0 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
(IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))),z,u) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Exec ((SubFrom ((intloc (0 + 1)),(intloc 0))),(IExec ((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))),z,u))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . (SubFrom ((intloc (0 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (0 + 1)),(intloc 0)))) . (IExec ((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))),z,u)) is set
(Exec ((SubFrom ((intloc (0 + 1)),(intloc 0))),(IExec ((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))),z,u)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))),z,u)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),z,(IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),z,(IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
abs (bf + 1) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(u . (fsloc 0)) /. (bf + 1) is ext-real V36() V37() integer Element of INT
n3 is ext-real V36() V37() integer set
(u . (fsloc 0)) . (bf - x) is ext-real V36() V37() integer set
(IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),z,(IExec (p,z,u)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec ((while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0))))))))),z,(IExec (p,z,u)))) . (intloc (2 + 1)) is ext-real V36() V37() integer set
(IExec (p,z,u)) . (intloc (2 + 1)) is ext-real V36() V37() integer set
len ((IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)) . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)) . (intloc (3 + 1)) is ext-real V36() V37() integer set
x + ((IExec (p,z,u)) . (intloc (3 + 1))) is ext-real V36() V37() integer set
x + 0 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
len ((IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (intloc (0 + 1)) is ext-real V36() V37() integer set
(P + 1) - 1 is ext-real V36() V37() integer set
(len ((IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (fsloc 0))) - 1 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1)))))),z,(IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)))) . (fsloc 0)) . ((bf + 1) - x) is ext-real V36() V37() integer set
((IExec ((p ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))),z,u)) . (fsloc 0)) . (bf + 1) is ext-real V36() V37() integer set
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,(IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,(IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(bf + 1) - 0 is non empty ext-real positive non negative V36() V37() integer set
(bf - x) + 1 is ext-real V36() V37() integer set
i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
j is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len ((IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (fsloc 0))) - ((IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (intloc (0 + 1))) is ext-real V36() V37() integer set
j - 1 is ext-real V36() V37() integer set
i - 1 is ext-real V36() V37() integer set
y1 is ext-real V36() V37() integer set
((IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (fsloc 0)) . i is ext-real V36() V37() integer set
y2 is ext-real V36() V37() integer set
((IExec (((((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),z,u)) . (fsloc 0)) . j is ext-real V36() V37() integer set
(u . (fsloc 0)) . i is ext-real V36() V37() integer set
(u . (fsloc 0)) . j is ext-real V36() V37() integer set
((bf + 1) - x) + 1 is ext-real V36() V37() integer set
x2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(u . (fsloc 0)) . x2 is ext-real V36() V37() integer set
kn is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(u . (fsloc 0)) . kn is ext-real V36() V37() integer set
((bf + 1) - x) + 1 is ext-real V36() V37() integer set
x1 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
x2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(u . (fsloc 0)) . x2 is ext-real V36() V37() integer set
(u . (fsloc 0)) . x1 is ext-real V36() V37() integer set
x2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((bf + 1) - x) - 1 is ext-real V36() V37() integer set
(u . (fsloc 0)) . x2 is ext-real V36() V37() integer set
kn is ext-real V36() V37() integer set
i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
j is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
x1 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u)) . (fsloc 0)) . i is ext-real V36() V37() integer set
x2 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u)) . (fsloc 0)) . j is ext-real V36() V37() integer set
u is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
u . (intloc (0 + 1)) is ext-real V36() V37() integer set
u . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (u . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len (u . (fsloc 0))) - 1 is ext-real V36() V37() integer set
(len (u . (fsloc 0))) - (u . (intloc (0 + 1))) is ext-real V36() V37() integer set
z is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
s2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
i is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
Cs1i is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),z,u)) . (fsloc 0)) . s2 is ext-real V36() V37() integer set
P is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
P . (intloc (0 + 1)) is ext-real V36() V37() integer set
P . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (P . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len (P . (fsloc 0))) - 1 is ext-real V36() V37() integer set
(len (P . (fsloc 0))) - (P . (intloc (0 + 1))) is ext-real V36() V37() integer set
u is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
z is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
s2 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P)) . (fsloc 0)) . z is ext-real V36() V37() integer set
i is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
t is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
P is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
P . (intloc (0 + 1)) is ext-real V36() V37() integer set
P . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (P . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(len (P . (fsloc 0))) - 1 is ext-real V36() V37() integer set
(len (P . (fsloc 0))) - (P . (intloc (0 + 1))) is ext-real V36() V37() integer set
u is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
z is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
s2 is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P)) . (fsloc 0)) . z is ext-real V36() V37() integer set
i is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),u,P)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
(len (w . (fsloc 0))) - (w . (intloc (0 + 1))) is ext-real V36() V37() integer set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
z is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0)) . P is ext-real V36() V37() integer set
bf is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0)) . u is ext-real V36() V37() integer set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
z is ext-real V36() V37() integer set
(w . (fsloc 0)) . P is ext-real V36() V37() integer set
bf is ext-real V36() V37() integer set
(w . (fsloc 0)) . u is ext-real V36() V37() integer set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
z is ext-real V36() V37() integer set
(w . (fsloc 0)) . P is ext-real V36() V37() integer set
bf is ext-real V36() V37() integer set
(w . (fsloc 0)) . u is ext-real V36() V37() integer set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
z is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0)) . P is ext-real V36() V37() integer set
bf is ext-real V36() V37() integer set
((IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),d,w)) . (fsloc 0)) . u is ext-real V36() V37() integer set
q is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec (((fsloc 0)),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((fsloc 0)),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
len (p . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0)) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
(((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0))) is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() keeping_0 InitClosed InitHalting keepInt0_1 good V161(3, SCM+FSA ) set
Initialized p is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
p +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Exec (((intloc (1 + 1)) := (intloc 0)),(Initialized p)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA) is functional with_common_domain product-like set
K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) is non empty functional set
the Execution of SCM+FSA is non empty Relation-like the InstructionsF of SCM+FSA -defined K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))) -valued Function-like total V18( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) Function-yielding V151() Element of K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))))
K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))) is Relation-like set
K32(K33( the InstructionsF of SCM+FSA,K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA))))) is cup-closed diff-closed preBoolean set
the Execution of SCM+FSA . ((intloc (1 + 1)) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (1 + 1)) := (intloc 0))) . (Initialized p) is set
IExec ((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec (((intloc (5 + 1)) := (intloc 0)),(IExec ((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))),q,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (5 + 1)) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (5 + 1)) := (intloc 0))) . (IExec ((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))),q,p)) is set
(Exec (((intloc (5 + 1)) := (intloc 0)),(IExec ((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))),q,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec (((intloc (4 + 1)) := (intloc 0)),(IExec (((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))),q,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (4 + 1)) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (4 + 1)) := (intloc 0))) . (IExec (((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))),q,p)) is set
(Exec (((intloc (4 + 1)) := (intloc 0)),(IExec (((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))),q,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec (((intloc (3 + 1)) := (intloc 0)),(IExec ((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))),q,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (3 + 1)) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (3 + 1)) := (intloc 0))) . (IExec ((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))),q,p)) is set
(Exec (((intloc (3 + 1)) := (intloc 0)),(IExec ((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))),q,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec (((intloc (2 + 1)) := (intloc 0)),(Exec (((intloc (1 + 1)) := (intloc 0)),(Initialized p)))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (2 + 1)) := (intloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (2 + 1)) := (intloc 0))) . (Exec (((intloc (1 + 1)) := (intloc 0)),(Initialized p))) is set
(Exec (((intloc (2 + 1)) := (intloc 0)),(Exec (((intloc (1 + 1)) := (intloc 0)),(Initialized p))))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Exec (((intloc (1 + 1)) := (intloc 0)),(Initialized p))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Initialized p) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec (((intloc (0 + 1)) :=len (fsloc 0)),(IExec (((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))),q,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . ((intloc (0 + 1)) :=len (fsloc 0)) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . ((intloc (0 + 1)) :=len (fsloc 0))) . (IExec (((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))),q,p)) is set
(Exec (((intloc (0 + 1)) :=len (fsloc 0)),(IExec (((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))),q,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Exec ((SubFrom ((intloc (0 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
the Execution of SCM+FSA . (SubFrom ((intloc (0 + 1)),(intloc 0))) is Relation-like Function-like Element of K99((product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)),(product ( the Object-Kind of SCM+FSA (#) the ValuesF of SCM+FSA)))
( the Execution of SCM+FSA . (SubFrom ((intloc (0 + 1)),(intloc 0)))) . (IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)) is set
(Exec ((SubFrom ((intloc (0 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),q,(IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p))) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((Times ((intloc (0 + 1)),(((((((((intloc (1 + 1)) :=len (fsloc 0)) ";" (SubFrom ((intloc (1 + 1)),(intloc (0 + 1))))) ";" ((intloc (2 + 1)) := (intloc (1 + 1)))) ";" (AddTo ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (SubFrom ((intloc (3 + 1)),(intloc (3 + 1))))) ";" (while>0 ((intloc (1 + 1)),((((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1)))) ";" (SubFrom ((intloc (4 + 1)),(intloc (5 + 1))))) ";" (if>0 ((intloc (4 + 1)),(Macro (SubFrom ((intloc (1 + 1)),(intloc (1 + 1))))),((AddTo ((intloc (3 + 1)),(intloc 0))) ";" (SubFrom ((intloc (1 + 1)),(intloc 0)))))))))) ";" (Times ((intloc (3 + 1)),(((((((intloc (1 + 1)) := (intloc (2 + 1))) ";" (SubFrom ((intloc (2 + 1)),(intloc 0)))) ";" ((intloc (4 + 1)) := ((fsloc 0),(intloc (1 + 1))))) ";" ((intloc (5 + 1)) := ((fsloc 0),(intloc (2 + 1))))) ";" (((fsloc 0),(intloc (1 + 1))) := (intloc (5 + 1)))) ";" (((fsloc 0),(intloc (2 + 1))) := (intloc (4 + 1))))))))),q,(IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p)))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)) . (intloc (0 + 1)) is ext-real V36() V37() integer set
(Exec (((intloc (0 + 1)) :=len (fsloc 0)),(IExec (((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))),q,p)))) . (intloc (0 + 1)) is ext-real V36() V37() integer set
len ((IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p)) . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p)) . (intloc (0 + 1)) is ext-real V36() V37() integer set
(Exec ((SubFrom ((intloc (0 + 1)),(intloc 0))),(IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)))) . (intloc (0 + 1)) is ext-real V36() V37() integer set
(IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)) . (intloc 0) is ext-real V36() V37() integer set
((IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)) . (intloc (0 + 1))) - ((IExec ((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))),q,p)) . (intloc 0)) is ext-real V36() V37() integer set
(len ((IExec (((((((((intloc (1 + 1)) := (intloc 0)) ";" ((intloc (2 + 1)) := (intloc 0))) ";" ((intloc (3 + 1)) := (intloc 0))) ";" ((intloc (4 + 1)) := (intloc 0))) ";" ((intloc (5 + 1)) := (intloc 0))) ";" ((intloc (0 + 1)) :=len (fsloc 0))) ";" (SubFrom ((intloc (0 + 1)),(intloc 0)))),q,p)) . (fsloc 0))) - 1 is ext-real V36() V37() integer set
i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Cs1i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
((IExec (((fsloc 0)),q,p)) . (fsloc 0)) . i is ext-real V36() V37() integer set
((IExec (((fsloc 0)),q,p)) . (fsloc 0)) . Cs1i is ext-real V36() V37() integer set
Cs2i is ext-real V36() V37() integer set
x is ext-real V36() V37() integer set
dom () is non empty V53() countable V132() set
p is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
x is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
w is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput (w,x,p) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (w,x,p)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (w,x,p)) . (IC ) is set
d is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(fsloc 0) .--> d is V5() Relation-like the carrier of SCM+FSA -defined {(fsloc 0)} -defined Function-like one-to-one constant the_Values_of SCM+FSA -compatible V53() countable Function-yielding V151() set
{(fsloc 0)} is non empty V53() countable set
{(fsloc 0)} --> d is non empty Relation-like {(fsloc 0)} -defined {d} -valued Function-like constant total V18({(fsloc 0)},{d}) V53() countable Function-yielding V151() Element of K32(K33({(fsloc 0)},{d}))
{d} is non empty functional V53() V57() with_common_domain countable set
K33({(fsloc 0)},{d}) is Relation-like V53() countable set
K32(K33({(fsloc 0)},{d})) is cup-closed diff-closed preBoolean V53() V57() countable set
Initialized ((fsloc 0) .--> d) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable 0 -started set
((fsloc 0) .--> d) +* (Initialize ((intloc 0) .--> 1)) is Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible V53() countable 0 -started set
Bubble-Sort-Algorithm is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like V53() countable V95() set
q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
p is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(fsloc 0) .--> p is V5() Relation-like the carrier of SCM+FSA -defined {(fsloc 0)} -defined Function-like one-to-one constant the_Values_of SCM+FSA -compatible V53() countable Function-yielding V151() set
{(fsloc 0)} is non empty V53() countable set
{(fsloc 0)} --> p is non empty Relation-like {(fsloc 0)} -defined {p} -valued Function-like constant total V18({(fsloc 0)},{p}) V53() countable Function-yielding V151() Element of K32(K33({(fsloc 0)},{p}))
{p} is non empty functional V53() V57() with_common_domain countable set
K33({(fsloc 0)},{p}) is Relation-like V53() countable set
K32(K33({(fsloc 0)},{p})) is cup-closed diff-closed preBoolean V53() V57() countable set
(Initialize ((intloc 0) .--> 1)) +* ((fsloc 0) .--> p) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
x is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Result (x,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Result (x,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec (((fsloc 0)),x,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec (((fsloc 0)),x,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
x +* () is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
u is Relation-like NAT -defined REAL -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of REAL
dom ((fsloc 0) .--> p) is V5() V53() countable set
dom ((Initialize ((intloc 0) .--> 1)) +* ((fsloc 0) .--> p)) is V53() countable set
q . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
((Initialize ((intloc 0) .--> 1)) +* ((fsloc 0) .--> p)) . (fsloc 0) is set
((fsloc 0) .--> p) . (fsloc 0) is Relation-like Function-like set
dom (q . (fsloc 0)) is V53() countable V132() Element of K32(NAT)
dom u is V53() countable V132() Element of K32(NAT)
z is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
bf is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
len (q . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u . bf is ext-real V36() V37() set
u . z is ext-real V36() V37() set
((IExec (((fsloc 0)),x,q)) . (fsloc 0)) . bf is ext-real V36() V37() integer set
((IExec (((fsloc 0)),x,q)) . (fsloc 0)) . z is ext-real V36() V37() integer set
{(intloc 0),(IC )} is non empty V53() countable set
q +* (Initialize ((intloc 0) .--> 1)) is non empty Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible total 0 -started set
Initialized q is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total 0 -started set
Result ((x +* ()),(Initialized q)) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Result ((x +* ()),(Initialized q))) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
IExec ((),x,q) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(IExec ((),x,q)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
{(intloc 0),(IC ),(fsloc 0)} is V53() countable set
p is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(fsloc 0) .--> p is V5() Relation-like the carrier of SCM+FSA -defined {(fsloc 0)} -defined Function-like one-to-one constant the_Values_of SCM+FSA -compatible V53() countable Function-yielding V151() set
{(fsloc 0)} is non empty V53() countable set
{(fsloc 0)} --> p is non empty Relation-like {(fsloc 0)} -defined {p} -valued Function-like constant total V18({(fsloc 0)},{p}) V53() countable Function-yielding V151() Element of K32(K33({(fsloc 0)},{p}))
{p} is non empty functional V53() V57() with_common_domain countable set
K33({(fsloc 0)},{p}) is Relation-like V53() countable set
K32(K33({(fsloc 0)},{p})) is cup-closed diff-closed preBoolean V53() V57() countable set
Initialized ((fsloc 0) .--> p) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable 0 -started set
((fsloc 0) .--> p) +* (Initialize ((intloc 0) .--> 1)) is Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible V53() countable 0 -started set
{(fsloc 0),(intloc 0),(intloc 1),(intloc 2),(intloc 3),(intloc 4),(intloc 5),(intloc 6)} is V53() countable set
UsedInt*Loc () is V53() countable Element of K32(FinSeq-Locations)
UsedIntLoc () is V53() countable Element of K32(Int-Locations)
(UsedInt*Loc ()) \/ (UsedIntLoc ()) is V53() countable set
P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
z is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
bf is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput (bf,u,P) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (bf,u,P)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (bf,u,P)) . (IC ) is set
s2 is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Comput (s2,z,P) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (s2,z,P)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (s2,z,P)) . (IC ) is set
u . (intloc 0) is ext-real V36() V37() integer set
z . (intloc 0) is ext-real V36() V37() integer set
Comput (bf,u,11) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
Comput (s2,z,11) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
u . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
z . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
len (u . (fsloc 0)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
(Comput (bf,u,11)) . Cs2i is set
(Comput (s2,z,11)) . Cs2i is set
Cs2i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (s2,z,Cs2i) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (s2,z,Cs2i)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (s2,z,Cs2i)) . (IC ) is set
Cs2i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (bf,u,Cs2i) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC (Comput (bf,u,Cs2i)) is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
(Comput (bf,u,Cs2i)) . (IC ) is set
dom (Comput (s2,z,11)) is non empty set
dom (Comput (bf,u,11)) is non empty set
(Comput (bf,u,11)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (s2,z,11)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (bf,u,11)) . (IC ) is set
(Comput (s2,z,11)) . (IC ) is set
P is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
u is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
z is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
bf is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
s2 is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (z,P,s2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (z,P,s2)) . (intloc 0) is ext-real V36() V37() integer set
Comput (bf,u,s2) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (bf,u,s2)) . (intloc 0) is ext-real V36() V37() integer set
(Comput (z,P,s2)) . (IC ) is set
(Comput (bf,u,s2)) . (IC ) is set
(Comput (z,P,s2)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(Comput (bf,u,s2)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
P . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
u . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
P . (intloc 0) is ext-real V36() V37() integer set
u . (intloc 0) is ext-real V36() V37() integer set
Comput (z,P,0) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
IC P is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
P . (IC ) is set
IC u is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
u . (IC ) is set
dom (Initialized ((fsloc 0) .--> p)) is V53() countable set
u is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
z is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
bf is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
s2 is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
i is ext-real non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer Element of NAT
Comput (u,bf,i) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (u,bf,i)) | (dom (Initialized ((fsloc 0) .--> p))) is Relation-like the carrier of SCM+FSA -defined dom (Initialized ((fsloc 0) .--> p)) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
Comput (z,s2,i) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
(Comput (z,s2,i)) | (dom (Initialized ((fsloc 0) .--> p))) is Relation-like the carrier of SCM+FSA -defined dom (Initialized ((fsloc 0) .--> p)) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
dom (Comput (u,bf,i)) is non empty set
dom (Comput (z,s2,i)) is non empty set
i + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
10 + 1 is non empty ext-real positive non negative epsilon-transitive epsilon-connected ordinal natural V36() V37() integer V50() Element of NAT
x is set
(Comput (u,bf,i)) . x is set
(Comput (z,s2,i)) . x is set
(Comput (u,bf,i)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (z,s2,i)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (u,bf,i)) . x is set
(Comput (z,s2,i)) . x is set
(Comput (u,bf,i)) . x is set
(Comput (z,s2,i)) . x is set
(Comput (u,bf,i)) . x is set
(Comput (z,s2,i)) . x is set
(Comput (u,bf,i)) . x is set
(Comput (z,s2,i)) . x is set
(Comput (u,bf,i)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (z,s2,i)) | ((UsedInt*Loc ()) \/ (UsedIntLoc ())) is Relation-like the carrier of SCM+FSA -defined (UsedInt*Loc ()) \/ (UsedIntLoc ()) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (u,bf,i)) . x is set
(Comput (z,s2,i)) . x is set
(Comput (u,bf,i)) | {(intloc 0),(IC ),(fsloc 0)} is Relation-like the carrier of SCM+FSA -defined {(intloc 0),(IC ),(fsloc 0)} -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Comput (z,s2,i)) | {(intloc 0),(IC ),(fsloc 0)} is Relation-like the carrier of SCM+FSA -defined {(intloc 0),(IC ),(fsloc 0)} -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
x is set
w is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
(fsloc 0) .--> w is V5() Relation-like the carrier of SCM+FSA -defined {(fsloc 0)} -defined Function-like one-to-one constant the_Values_of SCM+FSA -compatible V53() countable Function-yielding V151() set
{(fsloc 0)} is non empty V53() countable set
{(fsloc 0)} --> w is non empty Relation-like {(fsloc 0)} -defined {w} -valued Function-like constant total V18({(fsloc 0)},{w}) V53() countable Function-yielding V151() Element of K32(K33({(fsloc 0)},{w}))
{w} is non empty functional V53() V57() with_common_domain countable set
K33({(fsloc 0)},{w}) is Relation-like V53() countable set
K32(K33({(fsloc 0)},{w})) is cup-closed diff-closed preBoolean V53() V57() countable set
d is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable data-only set
dom d is V53() countable set
(Initialize ((intloc 0) .--> 1)) +* d is Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible V53() countable 0 -started set
t is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
P is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
{(intloc 0)} is non empty V53() countable Element of K32(Int-Locations)
dom ((intloc 0) .--> 1) is V5() V53() countable set
(dom ((intloc 0) .--> 1)) \/ {(IC )} is non empty V53() countable set
{(IC )} \/ {(intloc 0)} is non empty V53() countable set
d +* (Initialize ((intloc 0) .--> 1)) is Relation-like the carrier of SCM+FSA -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible the_Values_of SCM+FSA -compatible V53() countable 0 -started set
u is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
z is non empty Relation-like NAT -defined the InstructionsF of SCM+FSA -valued Function-like total set
Sorting-Function . d is Relation-like Function-like set
Result ((),((Initialize ((intloc 0) .--> 1)) +* d)) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
Initialized d is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable 0 -started set
Result (P,t) is non empty Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible total set
dom (Result (P,t)) is non empty set
dom ((Initialize ((intloc 0) .--> 1)) +* d) is V53() countable set
(Result (P,t)) | (dom ((Initialize ((intloc 0) .--> 1)) +* d)) is Relation-like the carrier of SCM+FSA -defined dom ((Initialize ((intloc 0) .--> 1)) +* d) -defined the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Initialize ((intloc 0) .--> 1)) +* ((fsloc 0) .--> w) is Relation-like the carrier of SCM+FSA -defined Function-like the_Values_of SCM+FSA -compatible V53() countable set
(Result (P,t)) . (fsloc 0) is Relation-like NAT -defined INT -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of INT
u is Relation-like NAT -defined REAL -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of REAL
z is Relation-like NAT -defined REAL -valued Function-like V38() V39() V40() V53() countable FinSequence-like FinSubsequence-like FinSequence of REAL
(fsloc 0) .--> z is V5() Relation-like the carrier of SCM+FSA -defined {(fsloc 0)} -defined Function-like one-to-one constant V53() countable Function-yielding V151() set
{(fsloc 0)} --> z is non empty Relation-like {(fsloc 0)} -defined {z} -valued Function-like constant total V18({(fsloc 0)},{z}) V53() countable Function-yielding V151() Element of K32(K33({(fsloc 0)},{z}))
{z} is non empty functional V53() V57() with_common_domain countable set
K33({(fsloc 0)},{z}) is Relation-like V53() countable set
K32(K33({(fsloc 0)},{z})) is cup-closed diff-closed preBoolean V53() V57() countable set
dom ((fsloc 0) .--> z) is V5() V53() countable set
(fsloc 0) .--> u is V5() Relation-like the carrier of SCM+FSA -defined {(fsloc 0)} -defined Function-like one-to-one constant V53() countable Function-yielding V151() set
{(fsloc 0)} --> u is non empty Relation-like {(fsloc 0)} -defined {u} -valued Function-like constant total V18({(fsloc 0)},{u}) V53() countable Function-yielding V151() Element of K32(K33({(fsloc 0)},{u}))
{u} is non empty functional V53() V57() with_common_domain countable set
K33({(fsloc 0)},{u}) is Relation-like V53() countable set
K32(K33({(fsloc 0)},{u})) is cup-closed diff-closed preBoolean V53() V57() countable set