:: SCPISORT semantic presentation

REAL is set
NAT is non empty epsilon-transitive epsilon-connected ordinal V28() cardinal limit_cardinal Element of K32(REAL)
K32(REAL) is set
K350() is V44() V83(2) IC-Ins-separated strict V91(2) AMI-Struct over 2
2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
SCM-Memory is set
K380(NAT,SCM-Memory) is Element of SCM-Memory
K220() is non empty set
SCM-OK is Relation-like SCM-Memory -defined 2 -valued Function-like V40( SCM-Memory ,2) Element of K32(K33(SCM-Memory,2))
K33(SCM-Memory,2) is set
K32(K33(SCM-Memory,2)) is set
SCM-VAL is Relation-like 2 -defined Function-like V39(2) set
SCM-Exec is Relation-like K220() -defined K180(K208((SCM-OK (#) SCM-VAL)),K208((SCM-OK (#) SCM-VAL))) -valued Function-like V40(K220(),K180(K208((SCM-OK (#) SCM-VAL)),K208((SCM-OK (#) SCM-VAL)))) Element of K32(K33(K220(),K180(K208((SCM-OK (#) SCM-VAL)),K208((SCM-OK (#) SCM-VAL)))))
SCM-OK (#) SCM-VAL is Relation-like set
K208((SCM-OK (#) SCM-VAL)) is set
K180(K208((SCM-OK (#) SCM-VAL)),K208((SCM-OK (#) SCM-VAL))) is set
K33(K220(),K180(K208((SCM-OK (#) SCM-VAL)),K208((SCM-OK (#) SCM-VAL)))) is set
K32(K33(K220(),K180(K208((SCM-OK (#) SCM-VAL)),K208((SCM-OK (#) SCM-VAL))))) is set
AMI-Struct(# SCM-Memory,K380(NAT,SCM-Memory),K220(),SCM-OK,SCM-VAL,SCM-Exec #) is strict AMI-Struct over 2
the U1 of K350() is set
K314(2,K350()) is Relation-like non-empty the U1 of K350() -defined Function-like V39( the U1 of K350()) set
the Object-Kind of K350() is Relation-like the U1 of K350() -defined 2 -valued Function-like V40( the U1 of K350(),2) Element of K32(K33( the U1 of K350(),2))
K33( the U1 of K350(),2) is set
K32(K33( the U1 of K350(),2)) is set
the U7 of K350() is Relation-like 2 -defined Function-like V39(2) set
the Object-Kind of K350() (#) the U7 of K350() is Relation-like set
COMPLEX is set
NAT is non empty epsilon-transitive epsilon-connected ordinal V28() cardinal limit_cardinal set
K32(NAT) is V28() set
K32(NAT) is V28() set
9 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Segm 9 is Element of K32(NAT)
K219() is set
K32(SCM-Memory) is set
the InstructionsF of K350() is non empty Relation-like standard-ins V73() V74() V76() set
INT is set
SCMPDS is V44() V83(2) IC-Ins-separated strict strict V91(2) AMI-Struct over 2
the U1 of SCMPDS is set
the InstructionsF of SCMPDS is non empty Relation-like standard-ins V73() V74() V76() set
K314(2,SCMPDS) is Relation-like non-empty the U1 of SCMPDS -defined Function-like V39( the U1 of SCMPDS) set
the Object-Kind of SCMPDS is Relation-like the U1 of SCMPDS -defined 2 -valued Function-like V40( the U1 of SCMPDS,2) Element of K32(K33( the U1 of SCMPDS,2))
K33( the U1 of SCMPDS,2) is set
K32(K33( the U1 of SCMPDS,2)) is set
the U7 of SCMPDS is Relation-like 2 -defined Function-like V39(2) set
the Object-Kind of SCMPDS (#) the U7 of SCMPDS is Relation-like set
RAT is set
{} is empty epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V24() V25() integer V28() cardinal {} -element ext-real non positive non negative set
1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
0 is empty epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V24() V25() integer V28() cardinal {} -element ext-real non positive non negative Element of NAT
K111(1) is V24() V25() integer ext-real non positive Element of REAL
14 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
IC is Element of the U1 of SCMPDS
halt SCMPDS is parahalting Element of the InstructionsF of SCMPDS
halt the InstructionsF of SCMPDS is V75( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
5 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
{0,4,5,6,14} is Element of K32(NAT)
A is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
D is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j2 is Relation-like Function-like FinSequence-like set
len j2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
dom j2 is Element of K32(NAT)
j3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
j2 . j3 is set
j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j1 + j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (j1 + j4) is Int-like Element of the U1 of SCMPDS
K359((j1 + j4)) is Int-like Element of the U1 of K350()
[1,(j1 + j4)] is set
A . (intpos (j1 + j4)) is V24() V25() integer ext-real set
j3 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len j3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
dom j3 is Element of K32(NAT)
j3 . j4 is V24() V25() integer ext-real set
j1 + j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (j1 + j4) is Int-like Element of the U1 of SCMPDS
K359((j1 + j4)) is Int-like Element of the U1 of K350()
[1,(j1 + j4)] is set
A . (intpos (j1 + j4)) is V24() V25() integer ext-real set
A is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
D is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j2 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len j2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
A is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len A is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
D is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len D is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
A . j1 is V24() V25() integer ext-real set
D . j2 is V24() V25() integer ext-real set
A . j2 is V24() V25() integer ext-real set
D . j1 is V24() V25() integer ext-real set
Seg (len A) is Element of K32(NAT)
dom A is Element of K32(NAT)
j3 is set
j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
A . j3 is V24() V25() integer ext-real set
D . j3 is V24() V25() integer ext-real set
dom D is Element of K32(NAT)
SCM-Data-Loc is Element of K32(SCM-Memory)
j1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize j1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
j1 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
DataPart j1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
Data-Locations is Element of K32( the U1 of SCMPDS)
K32( the U1 of SCMPDS) is set
j1 | (Data-Locations ) is Relation-like set
DataPart j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
j2 | (Data-Locations ) is Relation-like set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
j4 is shiftable parahalting Element of the InstructionsF of SCMPDS
j3 ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
Load j4 is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() V81( SCMPDS ) set
Initialize j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
j2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec (j3,j1,(Initialize j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j3 ';' (Load j4) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
IExec (j3,j1,j2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec (j3,j1,j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (j3,j1,j2)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() paraclosed parahalting shiftable set
j3 ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
IExec ((j3 ';' j4),j1,j2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (j4,j1,(Initialize (IExec (j3,j1,j2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
k1 is Int-like Element of the U1 of SCMPDS
(IExec ((j3 ';' j4),j1,j2)) . k1 is V24() V25() integer ext-real set
(IExec (j4,j1,(Initialize (IExec (j3,j1,j2))))) . k1 is V24() V25() integer ext-real set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting set
IExec (j3,j1,j2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec (j3,j1,j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (j3,j1,j2)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() shiftable set
j3 ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
IExec ((j3 ';' j4),j1,j2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (j4,j1,(Initialize (IExec (j3,j1,j2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
k1 is Int-like Element of the U1 of SCMPDS
(IExec ((j3 ';' j4),j1,j2)) . k1 is V24() V25() integer ext-real set
(IExec (j4,j1,(Initialize (IExec (j3,j1,j2))))) . k1 is V24() V25() integer ext-real set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() paraclosed parahalting shiftable set
j3 ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
Initialize j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
j2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec (j3,j1,(Initialize j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
j2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() paraclosed parahalting set
IExec (j3,j1,(Initialize j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() shiftable set
j3 ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j4 is shiftable parahalting Element of the InstructionsF of SCMPDS
j3 ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
Load j4 is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() V81( SCMPDS ) set
Initialize j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
j2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec (j3,j1,(Initialize j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
j3 ';' (Load j4) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j1 is Int-like Element of the U1 of SCMPDS
j2 is V24() V25() integer ext-real set
j3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
for-down (j1,j2,j3,j4) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
stop (for-down (j1,j2,j3,j4)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
K305(SCMPDS) is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() non halt-free V80( SCMPDS ) V81( SCMPDS ) paraclosed parahalting shiftable set
Load is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() V81( SCMPDS ) set
(for-down (j1,j2,j3,j4)) ';' K305(SCMPDS) is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
card (stop (for-down (j1,j2,j3,j4))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (stop (for-down (j1,j2,j3,j4))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card j4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card j4) + 4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (for-down (j1,j2,j3,j4)) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (for-down (j1,j2,j3,j4)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (for-down (j1,j2,j3,j4))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(card j4) + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card j4) + 3) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
j1 is Int-like Element of the U1 of SCMPDS
j2 is V24() V25() integer ext-real set
j3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
- j3 is V24() V25() integer ext-real non positive set
AddTo (j1,j2,(- j3)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*j1,j2,(- j3)*> is set
K15(8,{},<*j1,j2,(- j3)*>) is set
j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
for-down (j1,j2,j3,j4) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
card j4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card j4) + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(j1,j2) <=0_goto ((card j4) + 3) is V77( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*j1,j2,((card j4) + 3)*> is set
K15(5,{},<*j1,j2,((card j4) + 3)*>) is set
j4 ';' (AddTo (j1,j2,(- j3))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
(card j4) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
- ((card j4) + 2) is V24() V25() integer ext-real non positive set
goto (- ((card j4) + 2)) is Element of the InstructionsF of SCMPDS
<*(- ((card j4) + 2))*> is Relation-like Function-like set
K15(14,{},<*(- ((card j4) + 2))*>) is set
(j4 ';' (AddTo (j1,j2,(- j3)))) ';' (goto (- ((card j4) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((j1,j2) <=0_goto ((card j4) + 3)) ';' ((j4 ';' (AddTo (j1,j2,(- j3)))) ';' (goto (- ((card j4) + 2)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((j1,j2) <=0_goto ((card j4) + 3)) ';' j4 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
(((j1,j2) <=0_goto ((card j4) + 3)) ';' j4) ';' (AddTo (j1,j2,(- j3))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((((j1,j2) <=0_goto ((card j4) + 3)) ';' j4) ';' (AddTo (j1,j2,(- j3)))) ';' (goto (- ((card j4) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j1 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
j2 is Int-like Element of the U1 of SCMPDS
j3 is V24() V25() integer ext-real set
j4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
- j4 is V24() V25() integer ext-real non positive set
AddTo (j2,j3,(- j4)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*j2,j3,(- j4)*> is set
K15(8,{},<*j2,j3,(- j4)*>) is set
j1 ';' (AddTo (j2,j3,(- j4))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
Shift ((j1 ';' (AddTo (j2,j3,(- j4)))),1) is Relation-like Function-like set
for-down (j2,j3,j4,j1) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
card j1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom j1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card j1) + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(j2,j3) <=0_goto ((card j1) + 3) is V77( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*j2,j3,((card j1) + 3)*> is set
K15(5,{},<*j2,j3,((card j1) + 3)*>) is set
(card j1) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
- ((card j1) + 2) is V24() V25() integer ext-real non positive set
goto (- ((card j1) + 2)) is Element of the InstructionsF of SCMPDS
<*(- ((card j1) + 2))*> is Relation-like Function-like set
K15(14,{},<*(- ((card j1) + 2))*>) is set
((j2,j3) <=0_goto ((card j1) + 3)) ';' j1 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
(((j2,j3) <=0_goto ((card j1) + 3)) ';' j1) ';' (AddTo (j2,j3,(- j4))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((((j2,j3) <=0_goto ((card j1) + 3)) ';' j1) ';' (AddTo (j2,j3,(- j4)))) ';' (goto (- ((card j1) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((j2,j3) <=0_goto ((card j1) + 3)) ';' (j1 ';' (AddTo (j2,j3,(- j4)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
(((j2,j3) <=0_goto ((card j1) + 3)) ';' (j1 ';' (AddTo (j2,j3,(- j4))))) ';' (goto (- ((card j1) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
Load ((j2,j3) <=0_goto ((card j1) + 3)) is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() halt-free V81( SCMPDS ) set
(Load ((j2,j3) <=0_goto ((card j1) + 3))) ';' (j1 ';' (AddTo (j2,j3,(- j4)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((Load ((j2,j3) <=0_goto ((card j1) + 3))) ';' (j1 ';' (AddTo (j2,j3,(- j4))))) ';' (goto (- ((card j1) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
Load (goto (- ((card j1) + 2))) is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() V81( SCMPDS ) set
((Load ((j2,j3) <=0_goto ((card j1) + 3))) ';' (j1 ';' (AddTo (j2,j3,(- j4))))) ';' (Load (goto (- ((card j1) + 2)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
card (Load ((j2,j3) <=0_goto ((card j1) + 3))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (Load ((j2,j3) <=0_goto ((card j1) + 3))) is non empty V5() epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal 1 -element V64() ext-real positive non negative set
F₆() is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
F₁() is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
F₄() is Int-like Element of the U1 of SCMPDS
F₁() . F₄() is V24() V25() integer ext-real set
F₅() is V24() V25() integer ext-real set
DataLoc ((F₁() . F₄()),F₅()) is Int-like Element of the U1 of SCMPDS
(F₁() . F₄()) + F₅() is V24() V25() integer ext-real set
K145(((F₁() . F₄()) + F₅())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((F₁() . F₄()) + F₅()))] is set
F₃() is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
- F₆() is V24() V25() integer ext-real non positive set
AddTo (F₄(),F₅(),(- F₆())) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*F₄(),F₅(),(- F₆())*> is set
K15(8,{},<*F₄(),F₅(),(- F₆())*>) is set
F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
for-down (F₄(),F₅(),F₆(),F₃()) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
F₂() is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
card F₃() is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom F₃() is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card F₃()) + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(F₄(),F₅()) <=0_goto ((card F₃()) + 3) is V77( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*F₄(),F₅(),((card F₃()) + 3)*> is set
K15(5,{},<*F₄(),F₅(),((card F₃()) + 3)*>) is set
(card F₃()) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
- ((card F₃()) + 2) is V24() V25() integer ext-real non positive set
goto (- ((card F₃()) + 2)) is Element of the InstructionsF of SCMPDS
<*(- ((card F₃()) + 2))*> is Relation-like Function-like set
K15(14,{},<*(- ((card F₃()) + 2))*>) is set
stop (for-down (F₄(),F₅(),F₆(),F₃())) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() V81( SCMPDS ) shiftable set
K305(SCMPDS) is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() non halt-free V80( SCMPDS ) V81( SCMPDS ) paraclosed parahalting shiftable set
Load is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() V81( SCMPDS ) set
(for-down (F₄(),F₅(),F₆(),F₃())) ';' K305(SCMPDS) is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() V81( SCMPDS ) shiftable set
(F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) ';' K305(SCMPDS) is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
k4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
k4 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
k5 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize k5 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
k5 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k5 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
k5 . F₄() is V24() V25() integer ext-real set
k6 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
dom (stop (for-down (F₄(),F₅(),F₆(),F₃()))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
- (- F₆()) is V24() V25() integer ext-real non negative set
- 1 is V24() V25() integer ext-real non positive set
(- F₆()) + (k5 . (DataLoc ((F₁() . F₄()),F₅()))) is V24() V25() integer ext-real set
(- 1) + (k5 . (DataLoc ((F₁() . F₄()),F₅()))) is V24() V25() integer ext-real set
(k5 . (DataLoc ((F₁() . F₄()),F₅()))) - 1 is V24() V25() integer ext-real set
k6 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃()))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) ';' (goto (- ((card F₃()) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((F₄(),F₅()) <=0_goto ((card F₃()) + 3)) ';' ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) ';' (goto (- ((card F₃()) + 2)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(0 + 1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Following ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0))) is Element of the InstructionsF of SCMPDS
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0)) . (IC ) is set
K179( the InstructionsF of SCMPDS,(k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0)))) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0)))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0))))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0))))) . (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,0)) is set
Following ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5) is Element of the InstructionsF of SCMPDS
IC k5 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
k5 . (IC ) is set
K179( the InstructionsF of SCMPDS,(k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC k5)) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5)),k5) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5))) . k5 is set
Exec (((F₄(),F₅()) <=0_goto ((card F₃()) + 3)),k5) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((F₄(),F₅()) <=0_goto ((card F₃()) + 3))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((F₄(),F₅()) <=0_goto ((card F₃()) + 3))) . k5 is set
WH is Int-like Element of the U1 of SCMPDS
k5 . WH is V24() V25() integer ext-real set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)) . WH is V24() V25() integer ext-real set
DataPart k5 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
Data-Locations is Element of K32( the U1 of SCMPDS)
K32( the U1 of SCMPDS) is set
k5 | (Data-Locations ) is Relation-like set
DataPart (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)) | (Data-Locations ) is Relation-like set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(k5 . (DataLoc ((F₁() . F₄()),F₅()))) - F₆() is V24() V25() integer ext-real set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5)) . F₄() is V24() V25() integer ext-real set
LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(card F₃()) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
DataLoc ((k5 . F₄()),F₅()) is Int-like Element of the U1 of SCMPDS
(k5 . F₄()) + F₅() is V24() V25() integer ext-real set
K145(((k5 . F₄()) + F₅())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((k5 . F₄()) + F₅()))] is set
k5 . (DataLoc ((k5 . F₄()),F₅())) is V24() V25() integer ext-real set
dom (for-down (F₄(),F₅(),F₆(),F₃())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))) +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Shift ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),1) is Relation-like Function-like set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)) . (IC ) is set
succ (IC k5) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative set
Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataPart (Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) | (Data-Locations ) is Relation-like set
DataPart (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) | (Data-Locations ) is Relation-like set
Result ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataPart (Result ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Result ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) | (Data-Locations ) is Relation-like set
DataPart (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5)) | (Data-Locations ) is Relation-like set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) . (IC ) is set
CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)))) is Element of the InstructionsF of SCMPDS
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))) . (IC ) is set
K179( the InstructionsF of SCMPDS,(k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))))) is Element of the InstructionsF of SCMPDS
(k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))) . ((card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) + 1) is Element of the InstructionsF of SCMPDS
(for-down (F₄(),F₅(),F₆(),F₃())) . ((card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) + 1) is set
Following ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec ((CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)))))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)))))) . (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))) is set
Exec ((goto (- ((card F₃()) + 2))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(goto (- ((card F₃()) + 2)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(goto (- ((card F₃()) + 2)))) . (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))) is set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))) . (IC ) is set
0 - ((card F₃()) + 2) is non empty V24() V25() integer ext-real non positive negative set
ICplusConst ((Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))),(0 - ((card F₃()) + 2))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Initialize (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
InsCode (goto (- ((card F₃()) + 2))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of InsCodes the InstructionsF of SCMPDS
InsCodes the InstructionsF of SCMPDS is non empty set
Initialize (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1))) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),k6,k5)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))) +* (stop (for-down (F₄(),F₅(),F₆(),F₃()))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(Result ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) . F₄() is V24() V25() integer ext-real set
(Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,(LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)))) . F₄() is V24() V25() integer ext-real set
(Result ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) . F₄() is V24() V25() integer ext-real set
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))) . F₄() is V24() V25() integer ext-real set
jf is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
B3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
B3 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
P is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,P)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,P)) . (IC ) is set
(IC (Comput ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5,P))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),P)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,1)),P)) . (IC ) is set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
a is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
a + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(card F₃()) + 4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (stop (for-down (F₄(),F₅(),F₆(),F₃()))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
jf is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
B3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1) + B3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
P is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))),P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Comput (((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))) +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,(((LifeSpan ((k6 +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),k5)) + 1) + 1))),P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((k6 +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),k5,jf)) . (IC ) is set
jf is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
k5 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k5 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
k5 . F₄() is V24() V25() integer ext-real set
k6 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
k4 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k4 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
k4 . F₄() is V24() V25() integer ext-real set
k5 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
k4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
k5 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k5 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
k5 . F₄() is V24() V25() integer ext-real set
k6 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
F₆() is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
F₁() is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
F₄() is Int-like Element of the U1 of SCMPDS
F₁() . F₄() is V24() V25() integer ext-real set
F₅() is V24() V25() integer ext-real set
DataLoc ((F₁() . F₄()),F₅()) is Int-like Element of the U1 of SCMPDS
(F₁() . F₄()) + F₅() is V24() V25() integer ext-real set
K145(((F₁() . F₄()) + F₅())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((F₁() . F₄()) + F₅()))] is set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
F₃() is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
- F₆() is V24() V25() integer ext-real non positive set
AddTo (F₄(),F₅(),(- F₆())) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*F₄(),F₅(),(- F₆())*> is set
K15(8,{},<*F₄(),F₅(),(- F₆())*>) is set
F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
for-down (F₄(),F₅(),F₆(),F₃()) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
F₂() is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (F₄(),F₅(),F₆(),F₃())),F₂(),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((for-down (F₄(),F₅(),F₆(),F₃())),F₂(),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
card F₃() is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom F₃() is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card F₃()) + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(F₄(),F₅()) <=0_goto ((card F₃()) + 3) is V77( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*F₄(),F₅(),((card F₃()) + 3)*> is set
K15(5,{},<*F₄(),F₅(),((card F₃()) + 3)*>) is set
(card F₃()) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
- ((card F₃()) + 2) is V24() V25() integer ext-real non positive set
goto (- ((card F₃()) + 2)) is Element of the InstructionsF of SCMPDS
<*(- ((card F₃()) + 2))*> is Relation-like Function-like set
K15(14,{},<*(- ((card F₃()) + 2))*>) is set
stop (for-down (F₄(),F₅(),F₆(),F₃())) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() V81( SCMPDS ) shiftable set
K305(SCMPDS) is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() non halt-free V80( SCMPDS ) V81( SCMPDS ) paraclosed parahalting shiftable set
Load is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() V81( SCMPDS ) set
(for-down (F₄(),F₅(),F₆(),F₃())) ';' K305(SCMPDS) is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃()))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() V81( SCMPDS ) shiftable set
(F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) ';' K305(SCMPDS) is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁()) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Initialize F₁() is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
F₁() +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))) +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
(F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) ';' (goto (- ((card F₃()) + 2))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
((F₄(),F₅()) <=0_goto ((card F₃()) + 3)) ';' ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) ';' (goto (- ((card F₃()) + 2)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(0 + 1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Following ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0))) is Element of the InstructionsF of SCMPDS
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0)) . (IC ) is set
K179( the InstructionsF of SCMPDS,(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0)))) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0)))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0))))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0))))) . (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),0)) is set
Following ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()) is Element of the InstructionsF of SCMPDS
IC F₁() is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
F₁() . (IC ) is set
K179( the InstructionsF of SCMPDS,(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC F₁())) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁())),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()))) . F₁() is set
Exec (((F₄(),F₅()) <=0_goto ((card F₃()) + 3)),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((F₄(),F₅()) <=0_goto ((card F₃()) + 3))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((F₄(),F₅()) <=0_goto ((card F₃()) + 3))) . F₁() is set
(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card F₃()) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁()))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (for-down (F₄(),F₅(),F₆(),F₃())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
a2 is Int-like Element of the U1 of SCMPDS
F₁() . a2 is V24() V25() integer ext-real set
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)) . a2 is V24() V25() integer ext-real set
DataPart F₁() is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
Data-Locations is Element of K32( the U1 of SCMPDS)
K32( the U1 of SCMPDS) is set
F₁() | (Data-Locations ) is Relation-like set
DataPart (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)) | (Data-Locations ) is Relation-like set
Shift ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),1) is Relation-like Function-like set
LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)) . (IC ) is set
succ (IC F₁()) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative set
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) . (IC ) is set
CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)))) is Element of the InstructionsF of SCMPDS
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))) . (IC ) is set
K179( the InstructionsF of SCMPDS,(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))))) is Element of the InstructionsF of SCMPDS
(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))) . ((card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) + 1) is Element of the InstructionsF of SCMPDS
(for-down (F₄(),F₅(),F₆(),F₃())) . ((card (F₃() ';' (AddTo (F₄(),F₅(),(- F₆()))))) + 1) is set
Following ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec ((CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)))))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)))))) . (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))) is set
Exec ((goto (- ((card F₃()) + 2))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(goto (- ((card F₃()) + 2)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(goto (- ((card F₃()) + 2)))) . (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))) is set
Comput ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁(),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁()))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataPart (Comput ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁(),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁(),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) | (Data-Locations ) is Relation-like set
DataPart (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) | (Data-Locations ) is Relation-like set
a5 is Int-like Element of the U1 of SCMPDS
dom (Start-At (0,SCMPDS)) is set
(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . a5 is V24() V25() integer ext-real set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())) . a5 is V24() V25() integer ext-real set
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),1)),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) . a5 is V24() V25() integer ext-real set
(Comput ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁(),(LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())))) . a5 is V24() V25() integer ext-real set
Result ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(Result ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) . a5 is V24() V25() integer ext-real set
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1))) . a5 is V24() V25() integer ext-real set
DataPart (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1))) | (Data-Locations ) is Relation-like set
DataPart (Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible data-only set
(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) | (Data-Locations ) is Relation-like set
a5 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
a5 . F₄() is V24() V25() integer ext-real set
a5 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
a6 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),a6,a5) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),a6,a5)) . F₄() is V24() V25() integer ext-real set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),a6,a5)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(a5 . (DataLoc ((F₁() . F₄()),F₅()))) - F₆() is V24() V25() integer ext-real set
Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),a6,a5)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),a6,a5)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄() is V24() V25() integer ext-real set
DataLoc (((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()),F₅()) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()) + F₅() is V24() V25() integer ext-real set
K145((((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()) + F₅())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()) + F₅()))] is set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())) . F₄() is V24() V25() integer ext-real set
jf is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
jf . F₄() is V24() V25() integer ext-real set
jf . (DataLoc (((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()),F₅())) is V24() V25() integer ext-real set
B3 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),B3,jf) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),B3,jf)) . F₄() is V24() V25() integer ext-real set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),B3,jf)) . (DataLoc (((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()),F₅())) is V24() V25() integer ext-real set
(jf . (DataLoc (((Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . F₄()),F₅()))) - F₆() is V24() V25() integer ext-real set
Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),B3,jf)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),B3,jf)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize (Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1) + 1))) . (IC ) is set
0 - ((card F₃()) + 2) is non empty V24() V25() integer ext-real non positive negative set
ICplusConst ((Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 1))),(0 - ((card F₃()) + 2))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
IC (Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))) . (IC ) is set
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2))) . (IC ) is set
CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2)))) is Element of the InstructionsF of SCMPDS
K179( the InstructionsF of SCMPDS,(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2))))) is Element of the InstructionsF of SCMPDS
jf is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + jf is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + (LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + (LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))),(LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + (LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))))))))) is Element of the InstructionsF of SCMPDS
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + (LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))))))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + (LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))))))) . (IC ) is set
K179( the InstructionsF of SCMPDS,(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(((LifeSpan ((F₂() +* (stop (F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))))),F₁())) + 2) + (LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))))))))) is Element of the InstructionsF of SCMPDS
B3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁(),(LifeSpan ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))),B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
CurInstr ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))),B3))) is Element of the InstructionsF of SCMPDS
IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))),B3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))),B3)) . (IC ) is set
K179( the InstructionsF of SCMPDS,(F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(IC (Comput ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁()))),B3)))) is Element of the InstructionsF of SCMPDS
Result ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Result ((F₂() +* (stop (for-down (F₄(),F₅(),F₆(),F₃())))),(Initialize (IExec ((F₃() ';' (AddTo (F₄(),F₅(),(- F₆())))),F₂(),F₁())))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
F₆() is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
F₁() is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
F₄() is Int-like Element of the U1 of SCMPDS
F₁() . F₄() is V24() V25() integer ext-real set
F₅() is V24() V25() integer ext-real set
DataLoc ((F₁() . F₄()),F₅()) is Int-like Element of the U1 of SCMPDS
(F₁() . F₄()) + F₅() is V24() V25() integer ext-real set
K145(((F₁() . F₄()) + F₅())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((F₁() . F₄()) + F₅()))] is set
F₂() is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
- F₆() is V24() V25() integer ext-real non positive set
AddTo (F₄(),F₅(),(- F₆())) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*F₄(),F₅(),(- F₆())*> is set
K15(8,{},<*F₄(),F₅(),(- F₆())*>) is set
F₂() ';' (AddTo (F₄(),F₅(),(- F₆()))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
for-down (F₄(),F₅(),F₆(),F₂()) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
F₃() is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (F₄(),F₅(),F₆(),F₂())),F₃(),F₁()) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),F₃(),F₁())) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
Initialize (IExec ((for-down (F₄(),F₅(),F₆(),F₂())),F₃(),F₁())) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),F₃(),F₁())) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
j3 . F₄() is V24() V25() integer ext-real set
j4 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (F₄(),F₅(),F₆(),F₂())),j4,j3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),j4,j3)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
Initialize (IExec ((for-down (F₄(),F₅(),F₆(),F₂())),j4,j3)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),j4,j3)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize j3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k1 is Int-like Element of the U1 of SCMPDS
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),j4,j3)) . k1 is V24() V25() integer ext-real set
j3 . k1 is V24() V25() integer ext-real set
j3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j3 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
j4 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j4 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
j4 . F₄() is V24() V25() integer ext-real set
k1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
Initialize (IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4)) . F₄() is V24() V25() integer ext-real set
Initialize (IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(j4 . (DataLoc ((F₁() . F₄()),F₅()))) - F₆() is V24() V25() integer ext-real set
((IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4)) . (DataLoc ((F₁() . F₄()),F₅()))) + 1 is V24() V25() integer ext-real set
DataLoc ((j4 . F₄()),F₅()) is Int-like Element of the U1 of SCMPDS
(j4 . F₄()) + F₅() is V24() V25() integer ext-real set
K145(((j4 . F₄()) + F₅())) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((j4 . F₄()) + F₅()))] is set
k4 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k4 . F₄() is V24() V25() integer ext-real set
k4 . (DataLoc ((j4 . F₄()),F₅())) is V24() V25() integer ext-real set
k5 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k5,k4) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k5,k4)) . F₄() is V24() V25() integer ext-real set
(IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k5,k4)) . (DataLoc ((j4 . F₄()),F₅())) is V24() V25() integer ext-real set
(k4 . (DataLoc ((j4 . F₄()),F₅()))) - F₆() is V24() V25() integer ext-real set
Initialize (IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k5,k4)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k5,k4)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j4 . (DataLoc ((j4 . F₄()),F₅())) is V24() V25() integer ext-real set
(Initialize (IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4))) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
(Initialize (IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4))) . F₄() is V24() V25() integer ext-real set
IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,(Initialize (IExec ((F₂() ';' (AddTo (F₄(),F₅(),(- F₆())))),k1,j4)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
j3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j4 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j4 . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
j4 . F₄() is V24() V25() integer ext-real set
k1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4)) . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
Initialize (IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((for-down (F₄(),F₅(),F₆(),F₂())),k1,j4)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
F₁() . (DataLoc ((F₁() . F₄()),F₅())) is V24() V25() integer ext-real set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
k2 is Int-like Element of the U1 of SCMPDS
j2 . k2 is V24() V25() integer ext-real set
k1 is Int-like Element of the U1 of SCMPDS
j2 . k1 is V24() V25() integer ext-real set
j4 is Int-like Element of the U1 of SCMPDS
j2 . j4 is V24() V25() integer ext-real set
k4 is V24() V25() integer ext-real set
(j2 . k2) + k4 is V24() V25() integer ext-real set
k3 is V24() V25() integer ext-real set
DataLoc ((j2 . j4),k3) is Int-like Element of the U1 of SCMPDS
(j2 . j4) + k3 is V24() V25() integer ext-real set
K145(((j2 . j4) + k3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((j2 . j4) + k3))] is set
k5 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
- k5 is V24() V25() integer ext-real non positive set
AddTo (j4,k3,(- k5)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*j4,k3,(- k5)*> is set
K15(8,{},<*j4,k3,(- k5)*>) is set
j3 ';' (AddTo (j4,k3,(- k5))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
for-down (j4,k3,k5,j3) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
FA is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
FA . j4 is V24() V25() integer ext-real set
FA . (DataLoc ((j2 . j4),k3)) is V24() V25() integer ext-real set
IF is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IF . k2 is V24() V25() integer ext-real set
(IF . k2) + k4 is V24() V25() integer ext-real set
IF . k1 is V24() V25() integer ext-real set
IF is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IF . k2 is V24() V25() integer ext-real set
(IF . k2) + k4 is V24() V25() integer ext-real set
IF . k1 is V24() V25() integer ext-real set
TR is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . j4 is V24() V25() integer ext-real set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . (DataLoc ((j2 . j4),k3)) is V24() V25() integer ext-real set
(FA . (DataLoc ((j2 . j4),k3))) - k5 is V24() V25() integer ext-real set
Initialize (IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B1 . k2 is V24() V25() integer ext-real set
(B1 . k2) + k4 is V24() V25() integer ext-real set
B1 . k1 is V24() V25() integer ext-real set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . k1 is V24() V25() integer ext-real set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . k2 is V24() V25() integer ext-real set
((IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . k2) + k4 is V24() V25() integer ext-real set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
k2 is Int-like Element of the U1 of SCMPDS
j2 . k2 is V24() V25() integer ext-real set
k1 is Int-like Element of the U1 of SCMPDS
j2 . k1 is V24() V25() integer ext-real set
j4 is Int-like Element of the U1 of SCMPDS
j2 . j4 is V24() V25() integer ext-real set
k4 is V24() V25() integer ext-real set
(j2 . k2) + k4 is V24() V25() integer ext-real set
k3 is V24() V25() integer ext-real set
DataLoc ((j2 . j4),k3) is Int-like Element of the U1 of SCMPDS
(j2 . j4) + k3 is V24() V25() integer ext-real set
K145(((j2 . j4) + k3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((j2 . j4) + k3))] is set
j2 . (DataLoc ((j2 . j4),k3)) is V24() V25() integer ext-real set
k5 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
- k5 is V24() V25() integer ext-real non positive set
AddTo (j4,k3,(- k5)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*j4,k3,(- k5)*> is set
K15(8,{},<*j4,k3,(- k5)*>) is set
j3 ';' (AddTo (j4,k3,(- k5))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
for-down (j4,k3,k5,j3) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
IExec ((for-down (j4,k3,k5,j3)),j1,j2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),j1,j2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),j1,j2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),j1,j2)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((for-down (j4,k3,k5,j3)),j1,(Initialize (IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),j1,j2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
FA is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
FA . j4 is V24() V25() integer ext-real set
FA . (DataLoc ((j2 . j4),k3)) is V24() V25() integer ext-real set
IF is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IF . k2 is V24() V25() integer ext-real set
(IF . k2) + k4 is V24() V25() integer ext-real set
IF . k1 is V24() V25() integer ext-real set
IF is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IF . k2 is V24() V25() integer ext-real set
(IF . k2) + k4 is V24() V25() integer ext-real set
IF . k1 is V24() V25() integer ext-real set
TR is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . j4 is V24() V25() integer ext-real set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . (DataLoc ((j2 . j4),k3)) is V24() V25() integer ext-real set
(FA . (DataLoc ((j2 . j4),k3))) - k5 is V24() V25() integer ext-real set
Initialize (IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B1 . k2 is V24() V25() integer ext-real set
(B1 . k2) + k4 is V24() V25() integer ext-real set
B1 . k1 is V24() V25() integer ext-real set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . k1 is V24() V25() integer ext-real set
(IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . k2 is V24() V25() integer ext-real set
((IExec ((j3 ';' (AddTo (j4,k3,(- k5)))),TR,FA)) . k2) + k4 is V24() V25() integer ext-real set
j1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
j2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
j3 is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
j4 is Int-like Element of the U1 of SCMPDS
j2 . j4 is V24() V25() integer ext-real set
k1 is V24() V25() integer ext-real set
DataLoc ((j2 . j4),k1) is Int-like Element of the U1 of SCMPDS
(j2 . j4) + k1 is V24() V25() integer ext-real set
K145(((j2 . j4) + k1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((j2 . j4) + k1))] is set
j2 . (DataLoc ((j2 . j4),k1)) is V24() V25() integer ext-real set
k2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
for-down (j4,k1,k2,j3) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) shiftable set
k3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
k3 . j4 is V24() V25() integer ext-real set
k4 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (j3,k4,k3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (j3,k4,k3)) . j4 is V24() V25() integer ext-real set
(IExec (j3,k4,k3)) . (DataLoc ((j2 . j4),k1)) is V24() V25() integer ext-real set
k3 . (DataLoc ((j2 . j4),k1)) is V24() V25() integer ext-real set
k5 is Int-like Element of the U1 of SCMPDS
(IExec (j3,k4,k3)) . k5 is V24() V25() integer ext-real set
k3 . k5 is V24() V25() integer ext-real set
GBP is Int-like Element of the U1 of SCMPDS
intpos 0 is Int-like Element of the U1 of SCMPDS
K359(0) is Int-like Element of the U1 of K350()
[1,0] is set
GBP := 0 is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,0*> is set
K15(2,{},<*GBP,0*>) is set
(GBP,1) := 0 is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
7 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*GBP,1,0*> is set
K15(7,{},<*GBP,1,0*>) is set
(GBP := 0) ';' ((GBP,1) := 0) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
j1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
j1 - 1 is V24() V25() integer ext-real set
(GBP,2) := (j1 - 1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,2,(j1 - 1)*> is set
K15(7,{},<*GBP,2,(j1 - 1)*>) is set
((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (j1 - 1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
j2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(GBP,3) := j2 is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,3,j2*> is set
K15(7,{},<*GBP,3,j2*>) is set
(((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (j1 - 1))) ';' ((GBP,3) := j2) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
AddTo (GBP,3,1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
<*GBP,3,1*> is set
K15(8,{},<*GBP,3,1*>) is set
(GBP,4) := (GBP,3) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
AddTo (GBP,1,1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,1,1*> is set
K15(8,{},<*GBP,1,1*>) is set
((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
(GBP,6) := (GBP,1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
intpos 4 is Int-like Element of the U1 of SCMPDS
K359(4) is Int-like Element of the U1 of K350()
[1,4] is set
- 1 is V24() V25() integer ext-real non positive set
(GBP,5) := ((intpos 4),(- 1)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,5,(intpos 4),0) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
((intpos 4),(- 1)) := ((intpos 4),0) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
((intpos 4),0) := (GBP,5) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
AddTo (GBP,4,(- 1)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,4,(- 1)*> is set
K15(8,{},<*GBP,4,(- 1)*>) is set
((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
AddTo (GBP,6,(- 1)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,6,(- 1)*> is set
K15(8,{},<*GBP,6,(- 1)*>) is set
(((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
(GBP,6) := 0 is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,6,0*> is set
K15(7,{},<*GBP,6,0*>) is set
Load ((GBP,6) := 0) is non empty V5() Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() 1 -element V71() halt-free V81( SCMPDS ) set
if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
(((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (j1 - 1))) ';' ((GBP,3) := j2)) ';' (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
card ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
10 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0)))) + (card (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + (card (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card (Load ((GBP,6) := 0)) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (Load ((GBP,6) := 0)) is non empty V5() epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal 1 -element V64() ext-real positive non negative set
(card ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1))))) + (card (Load ((GBP,6) := 0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1))))) + (card (Load ((GBP,6) := 0)))) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + (((card ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1))))) + (card (Load ((GBP,6) := 0)))) + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1))))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1))))) + 1) + (card (Load ((GBP,6) := 0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((card (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1))))) + 1) + (card (Load ((GBP,6) := 0)))) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + ((((card (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1))))) + 1) + (card (Load ((GBP,6) := 0)))) + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5)))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5)))) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((card ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5)))) + 1) + 1) + (card (Load ((GBP,6) := 0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((((card ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5)))) + 1) + 1) + (card (Load ((GBP,6) := 0)))) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + (((((card ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5)))) + 1) + 1) + (card (Load ((GBP,6) := 0)))) + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)))) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)))) + 1) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((((card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)))) + 1) + 1) + 1) + (card (Load ((GBP,6) := 0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((((card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)))) + 1) + 1) + 1) + (card (Load ((GBP,6) := 0)))) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + ((((((card (((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0)))) + 1) + 1) + 1) + (card (Load ((GBP,6) := 0)))) + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(2 + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((2 + 1) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((2 + 1) + 1) + 1) + (card (Load ((GBP,6) := 0))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((((2 + 1) + 1) + 1) + (card (Load ((GBP,6) := 0)))) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + (((((2 + 1) + 1) + 1) + (card (Load ((GBP,6) := 0)))) + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((2 + 1) + 1) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((((2 + 1) + 1) + 1) + 1) + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + (((((2 + 1) + 1) + 1) + 1) + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
16 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1)))) + (card (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1)))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1)))) + 1) + (card (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card ((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card ((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3)))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card ((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3)))) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((card ((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3)))) + 1) + 1) + (card (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(2 + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((2 + 1) + 1) + (card (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
10 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((2 + 1) + 1) + (10 + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos 1 is Int-like Element of the U1 of SCMPDS
K359(1) is Int-like Element of the U1 of K350()
[1,1] is set
intpos 2 is Int-like Element of the U1 of SCMPDS
K359(2) is Int-like Element of the U1 of K350()
[1,2] is set
intpos 3 is Int-like Element of the U1 of SCMPDS
K359(3) is Int-like Element of the U1 of K350()
[1,3] is set
intpos 5 is Int-like Element of the U1 of SCMPDS
K359(5) is Int-like Element of the U1 of K350()
[1,5] is set
intpos 6 is Int-like Element of the U1 of SCMPDS
K359(6) is Int-like Element of the U1 of K350()
[1,6] is set
jf is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
B3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B3 . (intpos 6) is V24() V25() integer ext-real set
7 + (B3 . (intpos 6)) is V24() V25() integer ext-real set
B3 . (intpos 4) is V24() V25() integer ext-real set
B3 . GBP is V24() V25() integer ext-real set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos 1) is V24() V25() integer ext-real set
B3 . (intpos 1) is V24() V25() integer ext-real set
DataLoc ((B3 . (intpos 4)),(- 1)) is Int-like Element of the U1 of SCMPDS
(B3 . (intpos 4)) + (- 1) is V24() V25() integer ext-real set
K145(((B3 . (intpos 4)) + (- 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . (intpos 4)) + (- 1)))] is set
DataLoc ((B3 . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
(B3 . (intpos 4)) + 0 is V24() V25() integer ext-real set
K145(((B3 . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . (intpos 4)) + 0))] is set
7 + 0 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
Exec (((GBP,5) := ((intpos 4),(- 1))),B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,5) := ((intpos 4),(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,5) := ((intpos 4),(- 1)))) . B3 is set
IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataLoc ((B3 . GBP),5) is Int-like Element of the U1 of SCMPDS
(B3 . GBP) + 5 is V24() V25() integer ext-real set
K145(((B3 . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . GBP) + 5))] is set
0 + 5 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K359((0 + 5)) is Int-like Element of the U1 of K350()
[1,(0 + 5)] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP is V24() V25() integer ext-real set
DataLoc (((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5 is V24() V25() integer ext-real set
K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5))] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 4) is V24() V25() integer ext-real set
6 + (B3 . (intpos 6)) is V24() V25() integer ext-real set
1 + (6 + (B3 . (intpos 6))) is V24() V25() integer ext-real set
(B3 . (intpos 4)) - 1 is V24() V25() integer ext-real set
Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,5) := ((intpos 4),(- 1)))) . (Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . GBP is V24() V25() integer ext-real set
Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(SubFrom (GBP,5,(intpos 4),0))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(SubFrom (GBP,5,(intpos 4),0))) . (Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) is set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . GBP is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP is V24() V25() integer ext-real set
DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5 is V24() V25() integer ext-real set
K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5))] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 4) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 4) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
6 + 0 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1) is V24() V25() integer ext-real set
abs (((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1)) is V24() V25() ext-real Element of REAL
DataLoc (((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)),(- 1)) is Int-like Element of the U1 of SCMPDS
K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1)))] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),(- 1)) := ((intpos 4),0))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),(- 1)) := ((intpos 4),0))) . (Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 4) is V24() V25() integer ext-real set
((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0 is V24() V25() integer ext-real set
abs (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0) is V24() V25() ext-real Element of REAL
DataLoc (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
K145((((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0))] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),0) := (GBP,5))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),0) := (GBP,5))) . (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4 is V24() V25() integer ext-real set
K145((((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4))] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 1) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 1) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,4,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,4,(- 1)))) . (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6 is V24() V25() integer ext-real set
K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6))] is set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := 0)) . (Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) is set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) . (IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := 0)) . (Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) is set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) . (IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 1) is V24() V25() integer ext-real set
jf is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
B3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B3 . (intpos 6) is V24() V25() integer ext-real set
7 + (B3 . (intpos 6)) is V24() V25() integer ext-real set
B3 . (intpos 4) is V24() V25() integer ext-real set
B3 . GBP is V24() V25() integer ext-real set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos 2) is V24() V25() integer ext-real set
B3 . (intpos 2) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos 3) is V24() V25() integer ext-real set
B3 . (intpos 3) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos 6) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos 6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos 4) is V24() V25() integer ext-real set
(B3 . (intpos 4)) - 1 is V24() V25() integer ext-real set
DataLoc ((B3 . (intpos 4)),(- 1)) is Int-like Element of the U1 of SCMPDS
(B3 . (intpos 4)) + (- 1) is V24() V25() integer ext-real set
K145(((B3 . (intpos 4)) + (- 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . (intpos 4)) + (- 1)))] is set
B3 . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
DataLoc ((B3 . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
(B3 . (intpos 4)) + 0 is V24() V25() integer ext-real set
K145(((B3 . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . (intpos 4)) + 0))] is set
B3 . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(B3 . (intpos 6)) - 1 is V24() V25() integer ext-real set
Exec (((GBP,5) := ((intpos 4),(- 1))),B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,5) := ((intpos 4),(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,5) := ((intpos 4),(- 1)))) . B3 is set
IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
7 + 0 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
abs (B3 . (intpos 4)) is V24() V25() ext-real Element of REAL
Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,5) := ((intpos 4),(- 1)))) . (Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) is set
DataLoc ((B3 . GBP),5) is Int-like Element of the U1 of SCMPDS
(B3 . GBP) + 5 is V24() V25() integer ext-real set
K145(((B3 . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . GBP) + 5))] is set
0 + 5 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K359((0 + 5)) is Int-like Element of the U1 of K350()
[1,(0 + 5)] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP is V24() V25() integer ext-real set
DataLoc (((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5 is V24() V25() integer ext-real set
K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5))] is set
abs (((Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . GBP) + 5) is V24() V25() ext-real Element of REAL
abs ((B3 . (intpos 4)) + 0) is V24() V25() ext-real Element of REAL
abs ((B3 . GBP) + 5) is V24() V25() ext-real Element of REAL
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 5) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 4) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(SubFrom (GBP,5,(intpos 4),0))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(SubFrom (GBP,5,(intpos 4),0))) . (Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) is set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . GBP is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . GBP is V24() V25() integer ext-real set
DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5 is V24() V25() integer ext-real set
K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5))] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
abs (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 5) is V24() V25() ext-real Element of REAL
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 4) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 4) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),(- 1)) := ((intpos 4),0))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),(- 1)) := ((intpos 4),0))) . (Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
DataLoc (((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)),(- 1)) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1) is V24() V25() integer ext-real set
K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1)))] is set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc (((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 3) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 3) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 3) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
6 + (B3 . (intpos 6)) is V24() V25() integer ext-real set
1 + (6 + (B3 . (intpos 6))) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 2) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 2) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 2) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos 6) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 6) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 6) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 6) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6 is V24() V25() integer ext-real set
K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP),5)) is V24() V25() integer ext-real set
IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := 0)) . (Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) is set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
6 + 0 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
abs (((Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1)) is V24() V25() ext-real Element of REAL
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 4) is V24() V25() integer ext-real set
((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0 is V24() V25() integer ext-real set
abs (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0) is V24() V25() ext-real Element of REAL
DataLoc (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
K145((((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + 0))] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),0) := (GBP,5))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(((intpos 4),0) := (GBP,5))) . (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 4) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
abs ((B3 . (intpos 4)) + (- 1)) is V24() V25() ext-real Element of REAL
2 * (abs ((B3 . (intpos 4)) + (- 1))) is V24() V25() ext-real set
(2 * (abs ((B3 . (intpos 4)) + (- 1)))) + 1 is V24() V25() ext-real set
2 * ((B3 . (intpos 4)) - 1) is V24() V25() integer ext-real set
(2 * ((B3 . (intpos 4)) - 1)) + 1 is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4 is V24() V25() integer ext-real set
K145((((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4))] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP is V24() V25() integer ext-real set
Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,4,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,4,(- 1)))) . (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6))] is set
abs (((IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 6) is V24() V25() ext-real Element of REAL
0 + 4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K359((0 + 4)) is Int-like Element of the U1 of K350()
[1,(0 + 4)] is set
abs (((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 4) is V24() V25() ext-real Element of REAL
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) . (IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) . (IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 6) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 6) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 6) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 4) is V24() V25() integer ext-real set
((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)) + (- 1) is V24() V25() integer ext-real set
IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 6) is V24() V25() integer ext-real set
Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)))))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,6,(- 1)))) . (IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) is set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 6) is V24() V25() integer ext-real set
(B3 . (intpos 6)) + (- 1) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 4) is V24() V25() integer ext-real set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4) is V24() V25() integer ext-real set
(7 + (B3 . (intpos 6))) - 1 is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos t3) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos t3) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos t3) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos t3) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos t3) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos t3) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
t3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
intpos t3 is Int-like Element of the U1 of SCMPDS
K359(t3) is Int-like Element of the U1 of K350()
[1,t3] is set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos t3) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos t3) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos t3) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos t3) is V24() V25() integer ext-real set
B3 . (intpos t3) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),jf,B3)) . (intpos t3) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (intpos 5) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (intpos 5) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (intpos 5) is V24() V25() integer ext-real set
(B3 . (DataLoc ((B3 . (intpos 4)),(- 1)))) - (B3 . (DataLoc ((B3 . (intpos 4)),0))) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3)) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec ((SubFrom (GBP,5,(intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),B3)))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 5) is V24() V25() integer ext-real set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 5) is V24() V25() integer ext-real set
(Exec ((((intpos 4),(- 1)) := ((intpos 4),0)),(Exec (((GBP,5) := ((intpos 4),(- 1))),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (intpos 5) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (intpos 4)),0)) is V24() V25() integer ext-real set
DataLoc (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 5 is V24() V25() integer ext-real set
K145((((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP) + 5))] is set
(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc (((IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . GBP),5)) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec ((((intpos 4),0) := (GBP,5)),(IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(B3 . (DataLoc ((B3 . (intpos 4)),0))) - (B3 . (DataLoc ((B3 . (intpos 4)),0))) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec ((if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(IExec (((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,6,(- 1))),(IExec ((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
abs (((Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))) . GBP) + 6) is V24() V25() ext-real Element of REAL
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec ((Load ((GBP,6) := 0)),jf,(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
(Exec (((GBP,6) := 0),(Initialize (IExec ((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))),jf,B3))))) . (DataLoc ((B3 . (intpos 4)),0)) is V24() V25() integer ext-real set
jf is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
B3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B3 . GBP is V24() V25() integer ext-real set
DataLoc ((B3 . GBP),6) is Int-like Element of the U1 of SCMPDS
(B3 . GBP) + 6 is V24() V25() integer ext-real set
K145(((B3 . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . GBP) + 6))] is set
B3 . (DataLoc ((B3 . GBP),6)) is V24() V25() integer ext-real set
7 + (B3 . (DataLoc ((B3 . GBP),6))) is V24() V25() integer ext-real set
B3 . (intpos 4) is V24() V25() integer ext-real set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
{(intpos 4)} is non empty V5() 1 -element set
s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
s . (DataLoc ((B3 . GBP),6)) is V24() V25() integer ext-real set
7 + (s . (DataLoc ((B3 . GBP),6))) is V24() V25() integer ext-real set
s . GBP is V24() V25() integer ext-real set
f is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
s . (intpos 6) is V24() V25() integer ext-real set
7 + (s . (intpos 6)) is V24() V25() integer ext-real set
s . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . (DataLoc ((B3 . GBP),6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . (intpos 6) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . (intpos 6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . (intpos 4) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . (DataLoc ((B3 . GBP),6))) is V24() V25() integer ext-real set
p0 is Int-like Element of the U1 of SCMPDS
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),f,s)) . p0 is V24() V25() integer ext-real set
s is Int-like Element of the U1 of SCMPDS
B3 . s is V24() V25() integer ext-real set
jf is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
B3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
B3 . GBP is V24() V25() integer ext-real set
DataLoc ((B3 . GBP),6) is Int-like Element of the U1 of SCMPDS
(B3 . GBP) + 6 is V24() V25() integer ext-real set
K145(((B3 . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((B3 . GBP) + 6))] is set
B3 . (DataLoc ((B3 . GBP),6)) is V24() V25() integer ext-real set
7 + (B3 . (DataLoc ((B3 . GBP),6))) is V24() V25() integer ext-real set
B3 . (intpos 4) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),jf,B3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),jf,B3)) . GBP is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),jf,B3)) . (intpos 1) is V24() V25() integer ext-real set
B3 . (intpos 1) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),jf,B3)) . (intpos 2) is V24() V25() integer ext-real set
B3 . (intpos 2) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),jf,B3)) . (intpos 3) is V24() V25() integer ext-real set
B3 . (intpos 3) is V24() V25() integer ext-real set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
s . (intpos 6) is V24() V25() integer ext-real set
7 + (s . (intpos 6)) is V24() V25() integer ext-real set
s . (intpos 4) is V24() V25() integer ext-real set
s . GBP is V24() V25() integer ext-real set
s . (intpos 1) is V24() V25() integer ext-real set
s . (intpos 2) is V24() V25() integer ext-real set
s . (intpos 3) is V24() V25() integer ext-real set
f is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),f,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),f,s)) . GBP is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),f,s)) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),f,s)) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),f,s)) . (intpos 3) is V24() V25() integer ext-real set
DataLoc ((s . GBP),6) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 6 is V24() V25() integer ext-real set
K145(((s . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((s . GBP) + 6))] is set
s is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
s + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
f is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
f . (intpos 6) is V24() V25() integer ext-real set
7 + (f . (intpos 6)) is V24() V25() integer ext-real set
f . (intpos 4) is V24() V25() integer ext-real set
f . GBP is V24() V25() integer ext-real set
f . (intpos 1) is V24() V25() integer ext-real set
f . (intpos 2) is V24() V25() integer ext-real set
f . (intpos 3) is V24() V25() integer ext-real set
g is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . GBP is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . (intpos 3) is V24() V25() integer ext-real set
DataLoc ((f . GBP),6) is Int-like Element of the U1 of SCMPDS
(f . GBP) + 6 is V24() V25() integer ext-real set
K145(((f . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((f . GBP) + 6))] is set
f . (DataLoc ((f . GBP),6)) is V24() V25() integer ext-real set
f . (DataLoc ((f . GBP),6)) is V24() V25() integer ext-real set
{(intpos 4)} is non empty V5() 1 -element set
n is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
n . (DataLoc ((f . GBP),6)) is V24() V25() integer ext-real set
7 + (n . (DataLoc ((f . GBP),6))) is V24() V25() integer ext-real set
n . GBP is V24() V25() integer ext-real set
i1 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,n) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,n)) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,n)) . (DataLoc ((f . GBP),6)) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,n)) . (DataLoc ((f . GBP),6))) is V24() V25() integer ext-real set
Initialize n is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
n +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize (Initialize n) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize n) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,(Initialize (Initialize n))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(Initialize n) . GBP is V24() V25() integer ext-real set
n . (intpos 4) is V24() V25() integer ext-real set
(Initialize n) . (intpos 4) is V24() V25() integer ext-real set
n . (intpos 6) is V24() V25() integer ext-real set
(Initialize n) . (intpos 6) is V24() V25() integer ext-real set
7 + (n . (intpos 6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,(Initialize (Initialize n)))) . (intpos 6) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,(Initialize (Initialize n)))) . (intpos 6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,(Initialize (Initialize n)))) . (intpos 4) is V24() V25() integer ext-real set
i3 is Int-like Element of the U1 of SCMPDS
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i1,n)) . i3 is V24() V25() integer ext-real set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 1) is V24() V25() integer ext-real set
Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 6) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))) . (intpos 6) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . GBP is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 2) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))) . (intpos 2) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 3) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))) . (intpos 3) is V24() V25() integer ext-real set
((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 6)) + 1 is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)) . (intpos 6)) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))))) . (intpos 2) is V24() V25() integer ext-real set
7 + (f . (DataLoc ((f . GBP),6))) is V24() V25() integer ext-real set
i2 is Int-like Element of the U1 of SCMPDS
f . i2 is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),g,f))))) . GBP is V24() V25() integer ext-real set
f . (DataLoc ((f . GBP),6)) is V24() V25() integer ext-real set
B3 . (intpos 6) is V24() V25() integer ext-real set
B3 . (intpos 6) is V24() V25() integer ext-real set
s is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
f is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
f . (intpos 6) is V24() V25() integer ext-real set
7 + (f . (intpos 6)) is V24() V25() integer ext-real set
f . (intpos 4) is V24() V25() integer ext-real set
f . GBP is V24() V25() integer ext-real set
g is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . GBP is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . (intpos 1) is V24() V25() integer ext-real set
f . (intpos 1) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . (intpos 2) is V24() V25() integer ext-real set
f . (intpos 2) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),g,f)) . (intpos 3) is V24() V25() integer ext-real set
f . (intpos 3) is V24() V25() integer ext-real set
B3 . (intpos 6) is V24() V25() integer ext-real set
jf is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
P is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
P . GBP is V24() V25() integer ext-real set
IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . GBP is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . (intpos 1) is V24() V25() integer ext-real set
P . (intpos 1) is V24() V25() integer ext-real set
(P . (intpos 1)) + 1 is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . (intpos 2) is V24() V25() integer ext-real set
P . (intpos 2) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . (intpos 3) is V24() V25() integer ext-real set
P . (intpos 3) is V24() V25() integer ext-real set
(P . (intpos 3)) + 1 is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . (intpos 6) is V24() V25() integer ext-real set
Initialize P is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
P +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec ((AddTo (GBP,3,1)),P) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,3,1))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,3,1))) . P is set
(Initialize P) . GBP is V24() V25() integer ext-real set
DataLoc (((Initialize P) . GBP),3) is Int-like Element of the U1 of SCMPDS
((Initialize P) . GBP) + 3 is V24() V25() integer ext-real set
K145((((Initialize P) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize P) . GBP) + 3))] is set
0 + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 3) is Int-like Element of the U1 of SCMPDS
K359((0 + 3)) is Int-like Element of the U1 of K350()
[1,(0 + 3)] is set
(Exec ((AddTo (GBP,3,1)),P)) . GBP is V24() V25() integer ext-real set
DataLoc (((Exec ((AddTo (GBP,3,1)),P)) . GBP),4) is Int-like Element of the U1 of SCMPDS
((Exec ((AddTo (GBP,3,1)),P)) . GBP) + 4 is V24() V25() integer ext-real set
K145((((Exec ((AddTo (GBP,3,1)),P)) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec ((AddTo (GBP,3,1)),P)) . GBP) + 4))] is set
0 + 4 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K359((0 + 4)) is Int-like Element of the U1 of K350()
[1,(0 + 4)] is set
(Exec ((AddTo (GBP,3,1)),P)) . (intpos 2) is V24() V25() integer ext-real set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . (intpos 2) is V24() V25() integer ext-real set
Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,4) := (GBP,3))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,4) := (GBP,3))) . (Exec ((AddTo (GBP,3,1)),P)) is set
(Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P)))) . (intpos 2) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,3,1)),P)) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . (intpos 1) is V24() V25() integer ext-real set
(Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P)))) . (intpos 1) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,3,1)),P)) . (intpos 3) is V24() V25() integer ext-real set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . GBP is V24() V25() integer ext-real set
(Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P)))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . GBP),1) is Int-like Element of the U1 of SCMPDS
((IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . GBP) + 1 is V24() V25() integer ext-real set
K145((((IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . GBP) + 1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . GBP) + 1))] is set
0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 1) is Int-like Element of the U1 of SCMPDS
K359((0 + 1)) is Int-like Element of the U1 of K350()
[1,(0 + 1)] is set
DataLoc (((Exec ((AddTo (GBP,3,1)),P)) . GBP),3) is Int-like Element of the U1 of SCMPDS
((Exec ((AddTo (GBP,3,1)),P)) . GBP) + 3 is V24() V25() integer ext-real set
K145((((Exec ((AddTo (GBP,3,1)),P)) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec ((AddTo (GBP,3,1)),P)) . GBP) + 3))] is set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . (intpos 4) is V24() V25() integer ext-real set
(Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P)))) . (intpos 4) is V24() V25() integer ext-real set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . (intpos 4) is V24() V25() integer ext-real set
Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,1,1))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,1,1))) . (IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) is set
(Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)))) . (intpos 4) is V24() V25() integer ext-real set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . (intpos 2) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . (intpos 1) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)))) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . (intpos 3) is V24() V25() integer ext-real set
(Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P)))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . (intpos 3) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := (GBP,1))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,6) := (GBP,1))) . (IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) is set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . GBP is V24() V25() integer ext-real set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . (intpos 1) is V24() V25() integer ext-real set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . (intpos 2) is V24() V25() integer ext-real set
DataLoc (((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP),1) is Int-like Element of the U1 of SCMPDS
((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP) + 1 is V24() V25() integer ext-real set
K145((((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP) + 1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . GBP) + 1))] is set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . (intpos 3) is V24() V25() integer ext-real set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . (intpos 4) is V24() V25() integer ext-real set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . (intpos 6) is V24() V25() integer ext-real set
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos n is Int-like Element of the U1 of SCMPDS
K359(n) is Int-like Element of the U1 of K350()
[1,n] is set
(Exec ((AddTo (GBP,3,1)),P)) . (intpos n) is V24() V25() integer ext-real set
(Initialize P) . (intpos n) is V24() V25() integer ext-real set
P . (intpos n) is V24() V25() integer ext-real set
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos n is Int-like Element of the U1 of SCMPDS
K359(n) is Int-like Element of the U1 of K350()
[1,n] is set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . (intpos n) is V24() V25() integer ext-real set
(Exec (((GBP,4) := (GBP,3)),(Exec ((AddTo (GBP,3,1)),P)))) . (intpos n) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,3,1)),P)) . (intpos n) is V24() V25() integer ext-real set
P . (intpos n) is V24() V25() integer ext-real set
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos n is Int-like Element of the U1 of SCMPDS
K359(n) is Int-like Element of the U1 of K350()
[1,n] is set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . (intpos n) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,1,1)),(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)))) . (intpos n) is V24() V25() integer ext-real set
(IExec (((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))),jf,P)) . (intpos n) is V24() V25() integer ext-real set
P . (intpos n) is V24() V25() integer ext-real set
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos n is Int-like Element of the U1 of SCMPDS
K359(n) is Int-like Element of the U1 of K350()
[1,n] is set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),jf,P)) . (intpos n) is V24() V25() integer ext-real set
(Exec (((GBP,6) := (GBP,1)),(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)))) . (intpos n) is V24() V25() integer ext-real set
(IExec ((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))),jf,P)) . (intpos n) is V24() V25() integer ext-real set
P . (intpos n) is V24() V25() integer ext-real set
AddTo (GBP,2,(- 1)) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,2,(- 1)*> is set
K15(8,{},<*GBP,2,(- 1)*>) is set
(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
s . (intpos 1) is V24() V25() integer ext-real set
(s . (intpos 1)) + 7 is V24() V25() integer ext-real set
s . (intpos 3) is V24() V25() integer ext-real set
s . GBP is V24() V25() integer ext-real set
IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,s)) . GBP is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,s)) . (intpos 2) is V24() V25() integer ext-real set
s . (intpos 2) is V24() V25() integer ext-real set
(s . (intpos 2)) - 1 is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,s)) . (intpos 3) is V24() V25() integer ext-real set
(s . (intpos 3)) + 1 is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,s)) . (intpos 1) is V24() V25() integer ext-real set
(s . (intpos 1)) + 1 is V24() V25() integer ext-real set
IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
s +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . GBP is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))) . GBP is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . (intpos 6) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))) . (intpos 6) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . (intpos 3) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))) . (intpos 3) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . (intpos 2) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))) . (intpos 2) is V24() V25() integer ext-real set
7 + (s . (intpos 1)) is V24() V25() integer ext-real set
(7 + (s . (intpos 1))) + 1 is V24() V25() integer ext-real set
7 + ((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . (intpos 6)) is V24() V25() integer ext-real set
DataLoc (((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s)) . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . GBP is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . GBP) + 2 is V24() V25() integer ext-real set
K145((((IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . GBP) + 2))] is set
0 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K359((0 + 2)) is Int-like Element of the U1 of K350()
[1,(0 + 2)] is set
Exec ((AddTo (GBP,2,(- 1))),(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,2,(- 1)))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(AddTo (GBP,2,(- 1)))) . (IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) is set
(Exec ((AddTo (GBP,2,(- 1))),(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)))) . GBP is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,2,(- 1))),(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)))) . (intpos 2) is V24() V25() integer ext-real set
(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . (intpos 2) is V24() V25() integer ext-real set
((IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . (intpos 2)) + (- 1) is V24() V25() integer ext-real set
((IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . (intpos 2)) - 1 is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))))) . (intpos 2) is V24() V25() integer ext-real set
((IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))))) . (intpos 2)) - 1 is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,2,(- 1))),(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)))) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . (intpos 3) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))))) . (intpos 3) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,2,(- 1))),(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))))) . (intpos 1) is V24() V25() integer ext-real set
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos n is Int-like Element of the U1 of SCMPDS
K359(n) is Int-like Element of the U1 of K350()
[1,n] is set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,s)) . (intpos n) is V24() V25() integer ext-real set
(Exec ((AddTo (GBP,2,(- 1))),(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)))) . (intpos n) is V24() V25() integer ext-real set
(IExec ((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))),P,s)) . (intpos n) is V24() V25() integer ext-real set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),P,s))))) . (intpos n) is V24() V25() integer ext-real set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
a is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
a . (intpos 1) is V24() V25() integer ext-real set
(a . (intpos 1)) + 7 is V24() V25() integer ext-real set
a . (intpos 3) is V24() V25() integer ext-real set
a . GBP is V24() V25() integer ext-real set
DataLoc ((a . GBP),2) is Int-like Element of the U1 of SCMPDS
(a . GBP) + 2 is V24() V25() integer ext-real set
K145(((a . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((a . GBP) + 2))] is set
0 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K359((0 + 2)) is Int-like Element of the U1 of K350()
[1,(0 + 2)] is set
g is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize g is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
g +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
g . (intpos 1) is V24() V25() integer ext-real set
(g . (intpos 1)) + 7 is V24() V25() integer ext-real set
g . (intpos 3) is V24() V25() integer ext-real set
g . GBP is V24() V25() integer ext-real set
g . (DataLoc ((a . GBP),2)) is V24() V25() integer ext-real set
p0 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP is V24() V25() integer ext-real set
Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g))) . GBP is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g))) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . (intpos 6) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g))) . (intpos 6) is V24() V25() integer ext-real set
7 + (g . (intpos 1)) is V24() V25() integer ext-real set
(7 + (g . (intpos 1))) + 1 is V24() V25() integer ext-real set
(g . (intpos 3)) + 1 is V24() V25() integer ext-real set
IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . GBP is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (DataLoc ((a . GBP),2)) is V24() V25() integer ext-real set
(g . (DataLoc ((a . GBP),2))) - 1 is V24() V25() integer ext-real set
(g . (intpos 1)) + 1 is V24() V25() integer ext-real set
7 + ((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . (intpos 6)) is V24() V25() integer ext-real set
DataLoc (((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (intpos 1) is V24() V25() integer ext-real set
((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (intpos 1)) + 7 is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (intpos 3) is V24() V25() integer ext-real set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
a is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
a . (intpos 1) is V24() V25() integer ext-real set
(a . (intpos 1)) + 7 is V24() V25() integer ext-real set
a . (intpos 3) is V24() V25() integer ext-real set
a . GBP is V24() V25() integer ext-real set
a . (intpos 2) is V24() V25() integer ext-real set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),P,a) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,a) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,a)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,a)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),P,(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),P,a)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataLoc ((a . GBP),2) is Int-like Element of the U1 of SCMPDS
(a . GBP) + 2 is V24() V25() integer ext-real set
K145(((a . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((a . GBP) + 2))] is set
0 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K359((0 + 2)) is Int-like Element of the U1 of K350()
[1,(0 + 2)] is set
g is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize g is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
g +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
g . (intpos 1) is V24() V25() integer ext-real set
(g . (intpos 1)) + 7 is V24() V25() integer ext-real set
g . (intpos 3) is V24() V25() integer ext-real set
g . GBP is V24() V25() integer ext-real set
g . (DataLoc ((a . GBP),2)) is V24() V25() integer ext-real set
p0 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
7 + (g . (intpos 1)) is V24() V25() integer ext-real set
(7 + (g . (intpos 1))) + 1 is V24() V25() integer ext-real set
(g . (intpos 3)) + 1 is V24() V25() integer ext-real set
IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . GBP is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (DataLoc ((a . GBP),2)) is V24() V25() integer ext-real set
(g . (DataLoc ((a . GBP),2))) - 1 is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . (intpos 6) is V24() V25() integer ext-real set
(g . (intpos 1)) + 1 is V24() V25() integer ext-real set
7 + ((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . (intpos 6)) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP is V24() V25() integer ext-real set
Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g))) . GBP is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g))) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g))) . (intpos 6) is V24() V25() integer ext-real set
DataLoc (((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),p0,g)) . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (intpos 1) is V24() V25() integer ext-real set
((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (intpos 1)) + 7 is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),p0,g)) . (intpos 3) is V24() V25() integer ext-real set
23 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
P is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
a is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(P,a) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
P - 1 is V24() V25() integer ext-real set
(GBP,2) := (P - 1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,2,(P - 1)*> is set
K15(7,{},<*GBP,2,(P - 1)*>) is set
((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
(GBP,3) := a is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,3,a*> is set
K15(7,{},<*GBP,3,a*>) is set
(((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) ';' ((GBP,3) := a) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) ';' ((GBP,3) := a)) ';' (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
card (P,a) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (P,a) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) ';' ((GBP,3) := a)) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) ';' ((GBP,3) := a)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
card (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) ';' ((GBP,3) := a))) + (card (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card (((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom (((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card (((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1)))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card (((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (P - 1)))) + 1) + (card (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
card ((GBP := 0) ';' ((GBP,1) := 0)) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
dom ((GBP := 0) ';' ((GBP,1) := 0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
(card ((GBP := 0) ';' ((GBP,1) := 0))) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((card ((GBP := 0) ';' ((GBP,1) := 0))) + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(((card ((GBP := 0) ';' ((GBP,1) := 0))) + 1) + 1) + (card (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
2 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(2 + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
((2 + 1) + 1) + (card (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))))) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(card (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))) + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
4 + ((card (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))) + 3) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
P is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
a is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(a,P) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
a - 1 is V24() V25() integer ext-real set
(GBP,2) := (a - 1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,2,(a - 1)*> is set
K15(7,{},<*GBP,2,(a - 1)*>) is set
((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
(GBP,3) := P is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,3,P*> is set
K15(7,{},<*GBP,3,P*>) is set
(((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)) ';' (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
i2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i3 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec ((GBP := 0),(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(GBP := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(GBP := 0)) . (Initialize i2) is set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2))) . GBP is V24() V25() integer ext-real set
Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2))) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2)))) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2)))) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2))) . (intpos 3) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2)))) . (intpos 3) is V24() V25() integer ext-real set
(Exec ((GBP := 0),(Initialize i2))) . GBP is V24() V25() integer ext-real set
DataLoc (((Exec ((GBP := 0),(Initialize i2))) . GBP),1) is Int-like Element of the U1 of SCMPDS
((Exec ((GBP := 0),(Initialize i2))) . GBP) + 1 is V24() V25() integer ext-real set
K145((((Exec ((GBP := 0),(Initialize i2))) . GBP) + 1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec ((GBP := 0),(Initialize i2))) . GBP) + 1))] is set
0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 1) is Int-like Element of the U1 of SCMPDS
K359((0 + 1)) is Int-like Element of the U1 of K350()
[1,(0 + 1)] is set
(IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) . GBP is V24() V25() integer ext-real set
Exec (((GBP,1) := 0),(Exec ((GBP := 0),(Initialize i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,1) := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,1) := 0)) . (Exec ((GBP := 0),(Initialize i2))) is set
(Exec (((GBP,1) := 0),(Exec ((GBP := 0),(Initialize i2))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) . GBP) + 2 is V24() V25() integer ext-real set
K145((((IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) . GBP) + 2))] is set
0 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K359((0 + 2)) is Int-like Element of the U1 of K350()
[1,(0 + 2)] is set
(IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) . (intpos 1) is V24() V25() integer ext-real set
(Exec (((GBP,1) := 0),(Exec ((GBP := 0),(Initialize i2))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) . (intpos 1) is V24() V25() integer ext-real set
Exec (((GBP,2) := (a - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,2) := (a - 1))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,2) := (a - 1))) . (IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))) is set
(Exec (((GBP,2) := (a - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) . GBP is V24() V25() integer ext-real set
(Exec (((GBP,2) := (a - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),i3,(Initialize i2))))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) . GBP),3) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) . GBP) + 3 is V24() V25() integer ext-real set
K145((((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) . GBP) + 3))] is set
0 + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 3) is Int-like Element of the U1 of SCMPDS
K359((0 + 3)) is Int-like Element of the U1 of K350()
[1,(0 + 3)] is set
Exec (((GBP,3) := P),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,3) := P)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,3) := P)) . (IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))) is set
(Exec (((GBP,3) := P),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))))) . (intpos 3) is V24() V25() integer ext-real set
(Exec (((GBP,3) := P),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))))) . (intpos 1) is V24() V25() integer ext-real set
((IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))) ';' ((GBP,3) := P)),i3,(Initialize i2))) . (intpos 1)) + 7 is V24() V25() integer ext-real set
(Exec (((GBP,3) := P),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (a - 1))),i3,(Initialize i2))))) . GBP is V24() V25() integer ext-real set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
a is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
a . (intpos 6) is V24() V25() integer ext-real set
7 + (a . (intpos 6)) is V24() V25() integer ext-real set
a . (intpos 4) is V24() V25() integer ext-real set
a . GBP is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,a) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),P,a) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),P,a)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),P,a)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),P,a)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataLoc ((a . GBP),6) is Int-like Element of the U1 of SCMPDS
(a . GBP) + 6 is V24() V25() integer ext-real set
K145(((a . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((a . GBP) + 6))] is set
0 + 6 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K359((0 + 6)) is Int-like Element of the U1 of K350()
[1,(0 + 6)] is set
g is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Initialize g is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
g +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
{(intpos 4)} is non empty V5() 1 -element set
g . (DataLoc ((a . GBP),6)) is V24() V25() integer ext-real set
7 + (g . (DataLoc ((a . GBP),6))) is V24() V25() integer ext-real set
g . GBP is V24() V25() integer ext-real set
p0 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,(Initialize g)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
g . (intpos 6) is V24() V25() integer ext-real set
7 + (g . (intpos 6)) is V24() V25() integer ext-real set
g . (intpos 4) is V24() V25() integer ext-real set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,g) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,g)) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,g)) . (DataLoc ((a . GBP),6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,(Initialize g))) . (intpos 6) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,(Initialize g))) . (intpos 6)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,(Initialize g))) . (intpos 4) is V24() V25() integer ext-real set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,g)) . (DataLoc ((a . GBP),6))) is V24() V25() integer ext-real set
i1 is Int-like Element of the U1 of SCMPDS
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),p0,g)) . i1 is V24() V25() integer ext-real set
a . (DataLoc ((a . GBP),6)) is V24() V25() integer ext-real set
7 + (a . (DataLoc ((a . GBP),6))) is V24() V25() integer ext-real set
g is Int-like Element of the U1 of SCMPDS
a . g is V24() V25() integer ext-real set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
s . (intpos 6) is V24() V25() integer ext-real set
7 + (s . (intpos 6)) is V24() V25() integer ext-real set
s . (intpos 4) is V24() V25() integer ext-real set
s . GBP is V24() V25() integer ext-real set
(s . (intpos 4)) - (s . (intpos 6)) is V24() V25() integer ext-real set
((s . (intpos 4)) - (s . (intpos 6))) - 1 is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
f is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
g is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len f is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len g is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
i1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i1 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(i1 + 1) + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i2 . (intpos 6) is V24() V25() integer ext-real set
7 + (i2 . (intpos 6)) is V24() V25() integer ext-real set
i2 . (intpos 4) is V24() V25() integer ext-real set
i2 . GBP is V24() V25() integer ext-real set
(i2 . (intpos 4)) - (i2 . (intpos 6)) is V24() V25() integer ext-real set
((i2 . (intpos 4)) - (i2 . (intpos 6))) - 1 is V24() V25() integer ext-real set
i3 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,i2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
i4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
I4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len i4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Initialize i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
i2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
DataLoc ((i2 . (intpos 4)),(- 1)) is Int-like Element of the U1 of SCMPDS
(i2 . (intpos 4)) + (- 1) is V24() V25() integer ext-real set
K145(((i2 . (intpos 4)) + (- 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((i2 . (intpos 4)) + (- 1)))] is set
DataLoc ((i2 . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
(i2 . (intpos 4)) + 0 is V24() V25() integer ext-real set
K145(((i2 . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((i2 . (intpos 4)) + 0))] is set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP is V24() V25() integer ext-real set
p0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(p0 + 1) + (i1 + 1) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
DataLoc (p0,(i1 + 1)) is Int-like Element of the U1 of SCMPDS
p0 + (i1 + 1) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative set
K145((p0 + (i1 + 1))) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((p0 + (i1 + 1)))] is set
p0 + (i1 + 1) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (p0 + (i1 + 1)) is Int-like Element of the U1 of SCMPDS
K359((p0 + (i1 + 1))) is Int-like Element of the U1 of K350()
[1,(p0 + (i1 + 1))] is set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 6) is V24() V25() integer ext-real set
Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . (intpos 6) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . GBP is V24() V25() integer ext-real set
i2 . (DataLoc ((i2 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
i2 . (DataLoc ((i2 . (intpos 4)),0)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (DataLoc ((i2 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (DataLoc ((i2 . (intpos 4)),0)) is V24() V25() integer ext-real set
(i2 . (intpos 6)) - 1 is V24() V25() integer ext-real set
(i2 . (intpos 4)) - 1 is V24() V25() integer ext-real set
i1 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
p0 + (i1 + 2) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (p0 + (i1 + 2)) is Int-like Element of the U1 of SCMPDS
K359((p0 + (i1 + 2))) is Int-like Element of the U1 of K350()
[1,(p0 + (i1 + 2))] is set
7 + ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 6)) is V24() V25() integer ext-real set
t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
I4 . t4 is V24() V25() integer ext-real set
p0 + t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + t4) is Int-like Element of the U1 of SCMPDS
K359((p0 + t4)) is Int-like Element of the U1 of K350()
[1,(p0 + t4)] is set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,i2)) . (intpos (p0 + t4)) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))))) . (intpos (p0 + t4)) is V24() V25() integer ext-real set
t4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
t4 . i is V24() V25() integer ext-real set
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
i2 . (intpos (p0 + i)) is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
t4 . pi is V24() V25() integer ext-real set
i4 . pi is V24() V25() integer ext-real set
t4 . i is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
t4 . (i1 + 2) is V24() V25() integer ext-real set
i4 . (i1 + 1) is V24() V25() integer ext-real set
((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 4)) - ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 6)) is V24() V25() integer ext-real set
(((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 4)) - ((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos 6))) - 1 is V24() V25() integer ext-real set
t4 . (i1 + 1) is V24() V25() integer ext-real set
i4 . (i1 + 2) is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
t4 . i is V24() V25() integer ext-real set
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
I4 . i is V24() V25() integer ext-real set
I4 . pi is V24() V25() integer ext-real set
I4 . i is V24() V25() integer ext-real set
I4 . pi is V24() V25() integer ext-real set
I4 . i is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
t4 . i is V24() V25() integer ext-real set
I4 . pi is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
I4 . i is V24() V25() integer ext-real set
I4 . pi is V24() V25() integer ext-real set
I4 . i is V24() V25() integer ext-real set
I4 . pi is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
I4 . i is V24() V25() integer ext-real set
t4 . i is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
pi is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
I4 . i is V24() V25() integer ext-real set
i4 . pi is V24() V25() integer ext-real set
I4 . i is V24() V25() integer ext-real set
pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
t4 . pi is V24() V25() integer ext-real set
i is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
i4 . i is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i4 . i is V24() V25() integer ext-real set
t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
i4 . t4 is V24() V25() integer ext-real set
p0 + t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + t4) is Int-like Element of the U1 of SCMPDS
K359((p0 + t4)) is Int-like Element of the U1 of K350()
[1,(p0 + t4)] is set
i2 . (intpos (p0 + t4)) is V24() V25() integer ext-real set
DataLoc (((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP) + 6 is V24() V25() integer ext-real set
K145((((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP) + 6))] is set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (DataLoc (((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP),6)) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . (DataLoc (((IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . GBP),6)) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . (intpos (p0 + t4)) is V24() V25() integer ext-real set
(IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)) . (intpos (p0 + t4)) is V24() V25() integer ext-real set
DataLoc (((Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . GBP) + 6 is V24() V25() integer ext-real set
K145((((Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . GBP) + 6))] is set
(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . (DataLoc (((Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))) . GBP),6)) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))))) . (DataLoc ((i2 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize i2))) . (DataLoc ((i2 . (intpos 4)),(- 1))) is V24() V25() integer ext-real set
I4 . t4 is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))))) . (DataLoc ((i2 . (intpos 4)),0)) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize i2))) . (DataLoc ((i2 . (intpos 4)),0)) is V24() V25() integer ext-real set
I4 . t4 is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize (IExec (((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))),i3,i2))))) . (intpos (p0 + t4)) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i3,(Initialize i2))) . (intpos (p0 + t4)) is V24() V25() integer ext-real set
I4 . t4 is V24() V25() integer ext-real set
t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i4 . t4 is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
i4 . t4 is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
i4 . t4 is V24() V25() integer ext-real set
i4 . (i1 + 1) is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
i4 . t4 is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
i4 . t4 is V24() V25() integer ext-real set
i4 . i is V24() V25() integer ext-real set
t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i4 . t4 is V24() V25() integer ext-real set
I4 . t4 is V24() V25() integer ext-real set
t4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
I4 . t4 is V24() V25() integer ext-real set
0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
i1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i1 . (intpos 6) is V24() V25() integer ext-real set
7 + (i1 . (intpos 6)) is V24() V25() integer ext-real set
i1 . (intpos 4) is V24() V25() integer ext-real set
i1 . GBP is V24() V25() integer ext-real set
(i1 . (intpos 4)) - (i1 . (intpos 6)) is V24() V25() integer ext-real set
((i1 . (intpos 4)) - (i1 . (intpos 6))) - 1 is V24() V25() integer ext-real set
i2 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i2,i1) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
i3 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
i4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len i3 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len i4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Initialize i1 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
i1 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
DataLoc ((i1 . GBP),6) is Int-like Element of the U1 of SCMPDS
(i1 . GBP) + 6 is V24() V25() integer ext-real set
K145(((i1 . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((i1 . GBP) + 6))] is set
i1 . (DataLoc ((i1 . GBP),6)) is V24() V25() integer ext-real set
I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
i3 . I4 is V24() V25() integer ext-real set
p0 + I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + I4) is Int-like Element of the U1 of SCMPDS
K359((p0 + I4)) is Int-like Element of the U1 of K350()
[1,(p0 + I4)] is set
i1 . (intpos (p0 + I4)) is V24() V25() integer ext-real set
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i2,(Initialize i1)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),i2,(Initialize i1))) . (intpos (p0 + I4)) is V24() V25() integer ext-real set
i4 . I4 is V24() V25() integer ext-real set
I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i3 . I4 is V24() V25() integer ext-real set
i4 . I4 is V24() V25() integer ext-real set
I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i4 . I4 is V24() V25() integer ext-real set
i1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
f . i1 is V24() V25() integer ext-real set
g . i1 is V24() V25() integer ext-real set
i2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
g . i2 is V24() V25() integer ext-real set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
s . GBP is V24() V25() integer ext-real set
s . (intpos 2) is V24() V25() integer ext-real set
s . (intpos 3) is V24() V25() integer ext-real set
s . (intpos 1) is V24() V25() integer ext-real set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
f is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
g is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len f is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len g is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n - 1 is V24() V25() integer ext-real set
p0 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
1 + 0 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(s . (intpos 2)) + (s . (intpos 1)) is V24() V25() integer ext-real set
(n - 1) + 0 is V24() V25() integer ext-real set
n - (s . (intpos 2)) is V24() V25() integer ext-real set
i2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i3 . GBP is V24() V25() integer ext-real set
i3 . (intpos 2) is V24() V25() integer ext-real set
i3 . (intpos 1) is V24() V25() integer ext-real set
(i3 . (intpos 2)) + (i3 . (intpos 1)) is V24() V25() integer ext-real set
i2 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
t1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n - (i3 . (intpos 2)) is V24() V25() integer ext-real set
i3 . (intpos 3) is V24() V25() integer ext-real set
(i3 . (intpos 3)) - (i3 . (intpos 1)) is V24() V25() integer ext-real set
((i3 . (intpos 3)) - (i3 . (intpos 1))) - 1 is V24() V25() integer ext-real set
i4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
I4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
t2 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),t2,i3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
len i4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . GBP is V24() V25() integer ext-real set
Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3))) . GBP is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 4) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3))) . (intpos 4) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6) is V24() V25() integer ext-real set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3))) . (intpos 6) is V24() V25() integer ext-real set
(i3 . (intpos 3)) + 1 is V24() V25() integer ext-real set
(i3 . (intpos 1)) + 1 is V24() V25() integer ext-real set
p0 + ((i3 . (intpos 1)) + 1) is V24() V25() integer ext-real set
6 + ((i3 . (intpos 1)) + 1) is V24() V25() integer ext-real set
6 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(6 + 1) + (i3 . (intpos 1)) is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . GBP is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 2) is V24() V25() integer ext-real set
(i3 . (intpos 2)) - 1 is V24() V25() integer ext-real set
n - ((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 2)) is V24() V25() integer ext-real set
t1 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 1) is V24() V25() integer ext-real set
((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 2)) + ((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 1)) is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 3) is V24() V25() integer ext-real set
((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 3)) - ((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 1)) is V24() V25() integer ext-real set
(((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 3)) - ((IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos 1))) - 1 is V24() V25() integer ext-real set
((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 4)) - ((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6)) is V24() V25() integer ext-real set
(((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 4)) - ((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6))) - 1 is V24() V25() integer ext-real set
pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
I4 . pi is V24() V25() integer ext-real set
p0 + pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + pi) is Int-like Element of the U1 of SCMPDS
K359((p0 + pi)) is Int-like Element of the U1 of K350()
[1,(p0 + pi)] is set
(IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),t2,i3)) . (intpos (p0 + pi)) is V24() V25() integer ext-real set
Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),t2,(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),t2,(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3))))) . (intpos (p0 + pi)) is V24() V25() integer ext-real set
pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 + pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i4 . pi is V24() V25() integer ext-real set
intpos (p0 + pi) is Int-like Element of the U1 of SCMPDS
K359((p0 + pi)) is Int-like Element of the U1 of K350()
[1,(p0 + pi)] is set
i3 . (intpos (p0 + pi)) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos (p0 + pi)) is V24() V25() integer ext-real set
((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6)) + 1 is V24() V25() integer ext-real set
p0 + (((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6)) + 1) is V24() V25() integer ext-real set
6 + (((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6)) + 1) is V24() V25() integer ext-real set
(6 + 1) + ((IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos 6)) is V24() V25() integer ext-real set
t1 + (i2 + 1) is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
0 + t1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),t2,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
pi is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len pi is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
pi . i is V24() V25() integer ext-real set
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(IExec ((while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))),t2,(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3))))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i4 . i is V24() V25() integer ext-real set
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(Initialize (IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(IExec (((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))),t2,i3)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3))) . GBP is V24() V25() integer ext-real set
(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3))) . (intpos 2) is V24() V25() integer ext-real set
(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3))) . (intpos 3) is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
pi . i is V24() V25() integer ext-real set
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(Initialize (IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(IExec (((((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))) ';' (AddTo (GBP,2,(- 1)))),t2,i3)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
i3 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i3 . GBP is V24() V25() integer ext-real set
i3 . (intpos 2) is V24() V25() integer ext-real set
i3 . (intpos 1) is V24() V25() integer ext-real set
(i3 . (intpos 2)) + (i3 . (intpos 1)) is V24() V25() integer ext-real set
t2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n - (i3 . (intpos 2)) is V24() V25() integer ext-real set
i3 . (intpos 3) is V24() V25() integer ext-real set
(i3 . (intpos 3)) - (i3 . (intpos 1)) is V24() V25() integer ext-real set
((i3 . (intpos 3)) - (i3 . (intpos 1))) - 1 is V24() V25() integer ext-real set
I4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
t1 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
i4 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),i4,i3) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
len I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len t1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i2 . GBP is V24() V25() integer ext-real set
i2 . (intpos 2) is V24() V25() integer ext-real set
i2 . (intpos 1) is V24() V25() integer ext-real set
(i2 . (intpos 2)) + (i2 . (intpos 1)) is V24() V25() integer ext-real set
n - (i2 . (intpos 2)) is V24() V25() integer ext-real set
i2 . (intpos 3) is V24() V25() integer ext-real set
(i2 . (intpos 3)) - (i2 . (intpos 1)) is V24() V25() integer ext-real set
((i2 . (intpos 3)) - (i2 . (intpos 1))) - 1 is V24() V25() integer ext-real set
i3 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),i3,i2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
i4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
I4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len i4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
t1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Initialize i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i2 +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
DataLoc ((i2 . GBP),2) is Int-like Element of the U1 of SCMPDS
(i2 . GBP) + 2 is V24() V25() integer ext-real set
K145(((i2 . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145(((i2 . GBP) + 2))] is set
i2 . (DataLoc ((i2 . GBP),2)) is V24() V25() integer ext-real set
t2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative set
I4 . t2 is V24() V25() integer ext-real set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),i3,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
p0 + t2 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + t2) is Int-like Element of the U1 of SCMPDS
K359((p0 + t2)) is Int-like Element of the U1 of K350()
[1,(p0 + t2)] is set
(IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),i3,(Initialize i2))) . (intpos (p0 + t2)) is V24() V25() integer ext-real set
i2 . (intpos (p0 + t2)) is V24() V25() integer ext-real set
i4 . t2 is V24() V25() integer ext-real set
i1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
i2 is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
i2 . GBP is V24() V25() integer ext-real set
i2 . (intpos 2) is V24() V25() integer ext-real set
i2 . (intpos 1) is V24() V25() integer ext-real set
(i2 . (intpos 2)) + (i2 . (intpos 1)) is V24() V25() integer ext-real set
t1 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n - (i2 . (intpos 2)) is V24() V25() integer ext-real set
i2 . (intpos 3) is V24() V25() integer ext-real set
(i2 . (intpos 3)) - (i2 . (intpos 1)) is V24() V25() integer ext-real set
((i2 . (intpos 3)) - (i2 . (intpos 1))) - 1 is V24() V25() integer ext-real set
i4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
I4 is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
i3 is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),i3,i2) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
len i4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
len I4 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
(s . (intpos 3)) - (s . (intpos 1)) is V24() V25() integer ext-real set
((s . (intpos 3)) - (s . (intpos 1))) - 1 is V24() V25() integer ext-real set
P is Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V39( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
f is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len f is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
g is Relation-like NAT -defined INT -valued Function-like FinSequence-like V112() V113() V114() FinSequence of INT
len g is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
(n,(p0 + 1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() set
n - 1 is V24() V25() integer ext-real set
(GBP,2) := (n - 1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,2,(n - 1)*> is set
K15(7,{},<*GBP,2,(n - 1)*>) is set
((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
(GBP,3) := (p0 + 1) is V77( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,3,(p0 + 1)*> is set
K15(7,{},<*GBP,3,(p0 + 1)*>) is set
(((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1)) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) paraclosed parahalting shiftable set
((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))) ';' (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))) is non empty Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like T-Sequence-like V28() V71() halt-free V81( SCMPDS ) set
IExec ((n,(p0 + 1)),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
6 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
Exec ((GBP := 0),s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)) is set
K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))) -valued Function-like V40( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) Element of K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))))
K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))) is set
K32(K33( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))))) is set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(GBP := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,(GBP := 0)) . s is set
(Exec ((GBP := 0),s)) . GBP is V24() V25() integer ext-real set
DataLoc (((Exec ((GBP := 0),s)) . GBP),1) is Int-like Element of the U1 of SCMPDS
((Exec ((GBP := 0),s)) . GBP) + 1 is V24() V25() integer ext-real set
K145((((Exec ((GBP := 0),s)) . GBP) + 1)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((Exec ((GBP := 0),s)) . GBP) + 1))] is set
0 + 1 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 1) is Int-like Element of the U1 of SCMPDS
K359((0 + 1)) is Int-like Element of the U1 of K350()
[1,(0 + 1)] is set
(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . GBP is V24() V25() integer ext-real set
Exec (((GBP,1) := 0),(Exec ((GBP := 0),s))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,1) := 0)) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,1) := 0)) . (Exec ((GBP := 0),s)) is set
(Exec (((GBP,1) := 0),(Exec ((GBP := 0),s)))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . GBP) + 2 is V24() V25() integer ext-real set
K145((((IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . GBP) + 2))] is set
0 + 2 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K359((0 + 2)) is Int-like Element of the U1 of K350()
[1,(0 + 2)] is set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . GBP is V24() V25() integer ext-real set
Exec (((GBP,2) := (n - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,2) := (n - 1))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,2) := (n - 1))) . (IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) is set
(Exec (((GBP,2) := (n - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)))) . GBP is V24() V25() integer ext-real set
DataLoc (((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . GBP),3) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . GBP) + 3 is V24() V25() integer ext-real set
K145((((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
[1,K145((((IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . GBP) + 3))] is set
0 + 3 is non empty epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal V64() ext-real positive non negative Element of NAT
intpos (0 + 3) is Int-like Element of the U1 of SCMPDS
K359((0 + 3)) is Int-like Element of the U1 of K350()
[1,(0 + 3)] is set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos i is Int-like Element of the U1 of SCMPDS
K359(i) is Int-like Element of the U1 of K350()
[1,i] is set
(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . (intpos i) is V24() V25() integer ext-real set
(Exec (((GBP,1) := 0),(Exec ((GBP := 0),s)))) . (intpos i) is V24() V25() integer ext-real set
(Exec ((GBP := 0),s)) . (intpos i) is V24() V25() integer ext-real set
s . (intpos i) is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos i is Int-like Element of the U1 of SCMPDS
K359(i) is Int-like Element of the U1 of K350()
[1,i] is set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . (intpos i) is V24() V25() integer ext-real set
(Exec (((GBP,2) := (n - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)))) . (intpos i) is V24() V25() integer ext-real set
(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . (intpos i) is V24() V25() integer ext-real set
s . (intpos i) is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is non empty Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V28() 0 -started set
K347((IC ),0) is V5() INT -valued V112() V113() V114() V115() set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) +* (Start-At (0,SCMPDS)) is non empty Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) 0 -started set
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
Exec (((GBP,3) := (p0 + 1)),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,3) := (p0 + 1))) is Element of K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)))
K182( the InstructionsF of SCMPDS,K180(K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS)),K208(( the Object-Kind of SCMPDS (#) the U7 of SCMPDS))), the Execution of SCMPDS,((GBP,3) := (p0 + 1))) . (IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) is set
(Exec (((GBP,3) := (p0 + 1)),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
s . (intpos (p0 + i)) is V24() V25() integer ext-real set
f . i is V24() V25() integer ext-real set
(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)) . (intpos 1) is V24() V25() integer ext-real set
(Exec (((GBP,1) := 0),(Exec ((GBP := 0),s)))) . (intpos 1) is V24() V25() integer ext-real set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . (intpos 1) is V24() V25() integer ext-real set
(Exec (((GBP,2) := (n - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)))) . (intpos 1) is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) . GBP is V24() V25() integer ext-real set
(Exec (((GBP,3) := (p0 + 1)),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)))) . GBP is V24() V25() integer ext-real set
(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)) . (intpos 2) is V24() V25() integer ext-real set
(Exec (((GBP,2) := (n - 1)),(IExec (((GBP := 0) ';' ((GBP,1) := 0)),P,s)))) . (intpos 2) is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) . (intpos 3) is V24() V25() integer ext-real set
(Exec (((GBP,3) := (p0 + 1)),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)))) . (intpos 3) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s))) . (intpos 3) is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s))) . (intpos 1) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s))) . GBP is V24() V25() integer ext-real set
(IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) . (intpos 2) is V24() V25() integer ext-real set
(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s))) . (intpos 2) is V24() V25() integer ext-real set
(Exec (((GBP,3) := (p0 + 1)),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)))) . (intpos 1) is V24() V25() integer ext-real set
((IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)) . (intpos 1)) + 7 is V24() V25() integer ext-real set
i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
g . i is V24() V25() integer ext-real set
IExec ((((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))) ';' (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))))),P,s) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
p0 + i is epsilon-transitive epsilon-connected ordinal natural V24() V25() integer V28() cardinal ext-real non negative Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K359((p0 + i)) is Int-like Element of the U1 of K350()
[1,(p0 + i)] is set
(IExec ((((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))) ';' (for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0))))))))))),P,s)) . (intpos (p0 + i)) is V24() V25() integer ext-real set
IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),P,(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s)))) is Relation-like the U1 of SCMPDS -defined Function-like K314(2,SCMPDS) -compatible V39( the U1 of SCMPDS) set
(IExec ((for-down (GBP,2,1,(((((AddTo (GBP,3,1)) ';' ((GBP,4) := (GBP,3))) ';' (AddTo (GBP,1,1))) ';' ((GBP,6) := (GBP,1))) ';' (while>0 (GBP,6,((((GBP,5) := ((intpos 4),(- 1))) ';' (SubFrom (GBP,5,(intpos 4),0))) ';' (if>0 (GBP,5,((((((GBP,5) := ((intpos 4),(- 1))) ';' (((intpos 4),(- 1)) := ((intpos 4),0))) ';' (((intpos 4),0) := (GBP,5))) ';' (AddTo (GBP,4,(- 1)))) ';' (AddTo (GBP,6,(- 1)))),(Load ((GBP,6) := 0)))))))))),P,(Initialize (IExec (((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))) ';' ((GBP,3) := (p0 + 1))),P,s))))) . (intpos (p0 + i)) is V24() V25() integer ext-real set
(Exec (((GBP,3) := (p0 + 1)),(IExec ((((GBP := 0) ';' ((GBP,1) := 0)) ';' ((GBP,2) := (n - 1))),P,s)))) . (intpos 2) is V24() V25() integer ext-real set