SCPQSORT

:: SCPQSORT semantic presentation

REAL is V1() V45() set
NAT is V1() epsilon-transitive epsilon-connected ordinal Element of K6(REAL)
K6(REAL) is set
K388() is V69() with_non-empty_values IC-Ins-separated strict V108(2) AMI-Struct over 2
2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
the U1 of K388() is set
the_Values_of K388() is Relation-like non-empty the U1 of K388() -defined Function-like V23( the U1 of K388()) set
the Object-Kind of K388() is Relation-like the U1 of K388() -defined 2 -valued Function-like V27( the U1 of K388(),2) Element of K6(K7( the U1 of K388(),2))
K7( the U1 of K388(),2) is Relation-like set
K6(K7( the U1 of K388(),2)) is set
the ValuesF of K388() is V1() Relation-like 2 -defined Function-like V23(2) set
the Object-Kind of K388() (#) the ValuesF of K388() is Relation-like the U1 of K388() -defined Function-like V23( the U1 of K388()) set
COMPLEX is V1() V45() set
NAT is V1() epsilon-transitive epsilon-connected ordinal set
K6(NAT) is set
K6(NAT) is set
K7(NAT,REAL) is Relation-like set
K6(K7(NAT,REAL)) is set
K6(K6(REAL)) is set
RAT is V1() V45() set
K6(RAT) is set
ExtREAL is V1() set
9 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Segm 9 is Element of K6(NAT)
K266() is set
SCM-Memory is set
K6(SCM-Memory) is set
K7(SCM-Memory,2) is Relation-like set
K6(K7(SCM-Memory,2)) is set
SCM-OK is Relation-like SCM-Memory -defined 2 -valued Function-like V27( SCM-Memory ,2) Element of K6(K7(SCM-Memory,2))
SCM-VAL is V1() Relation-like 2 -defined Function-like V23(2) set
SCM-OK (#) SCM-VAL is Relation-like SCM-Memory -defined Function-like V23( SCM-Memory ) set
product (SCM-OK (#) SCM-VAL) is set
K267() is V1() set
K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL))) is set
K7(K267(),K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL)))) is Relation-like set
K6(K7(K267(),K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL))))) is set
the InstructionsF of K388() is V1() Relation-like V89() V90() V91() V93() set
INT is V1() V45() set
SCMPDS is V69() with_non-empty_values IC-Ins-separated strict strict V108(2) V176(2) V177(2) AMI-Struct over 2
K418(NAT,SCM-Memory) is Element of SCM-Memory
K547() is set
K567() is Relation-like K547() -defined K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL))) -valued Function-like V27(K547(),K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL)))) Element of K6(K7(K547(),K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL)))))
K7(K547(),K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL)))) is Relation-like set
K6(K7(K547(),K103((product (SCM-OK (#) SCM-VAL)),(product (SCM-OK (#) SCM-VAL))))) is set
AMI-Struct(# SCM-Memory,K418(NAT,SCM-Memory),K547(),SCM-OK,SCM-VAL,K567() #) is strict AMI-Struct over 2
the U1 of SCMPDS is set
the InstructionsF of SCMPDS is V1() Relation-like V89() V90() V91() V93() set
the_Values_of SCMPDS is Relation-like non-empty the U1 of SCMPDS -defined Function-like V23( the U1 of SCMPDS) set
the Object-Kind of SCMPDS is Relation-like the U1 of SCMPDS -defined 2 -valued Function-like V27( the U1 of SCMPDS,2) Element of K6(K7( the U1 of SCMPDS,2))
K7( the U1 of SCMPDS,2) is Relation-like set
K6(K7( the U1 of SCMPDS,2)) is set
the ValuesF of SCMPDS is V1() Relation-like 2 -defined Function-like V23(2) set
the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS is Relation-like the U1 of SCMPDS -defined Function-like V23( the U1 of SCMPDS) set
K2(K266(),INT) is V1() set
SCM-Data-Loc is Element of K6(SCM-Memory)
K2(SCM-Data-Loc,INT) is V1() set
1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
0 is V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() Element of NAT
the V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() set is V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() set
0 is V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() set
IC is Element of the U1 of SCMPDS
goto 1 is Element of the InstructionsF of SCMPDS
14 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*1*> is Relation-like Function-like set
K75(14,0,<*1*>) is set
- 1 is V11() V12() ext-real non positive integer set
goto (- 1) is Element of the InstructionsF of SCMPDS
<*(- 1)*> is Relation-like Function-like set
K75(14,0,<*(- 1)*>) is set
product (the_Values_of SCMPDS) is set
K7((product (the_Values_of SCMPDS)),NAT) is Relation-like set
K6(K7((product (the_Values_of SCMPDS)),NAT)) is set
GBP is Int-like Element of the U1 of SCMPDS
intpos 0 is Int-like Element of the U1 of SCMPDS
K397(0) is Int-like Element of the U1 of K388()
SBP is Int-like Element of the U1 of SCMPDS
intpos 1 is Int-like Element of the U1 of SCMPDS
K397(1) is Int-like Element of the U1 of K388()
i1 is Int-like Element of the U1 of SCMPDS
i2 is V11() V12() ext-real integer set
A is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() shiftable V160() set
D is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() shiftable V160() set
if>0 (i1,i2,A,D) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card A is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom A is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card A) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(i1,i2) <=0_goto ((card A) + 2) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*i1,i2,((card A) + 2)*> is set
K75(5,0,<*i1,i2,((card A) + 2)*>) is set
card D is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom D is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card D) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Goto ((card D) + 1) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
A ';' (Goto ((card D) + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(A ';' (Goto ((card D) + 1))) ';' D is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
goto ((card D) + 1) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*((card D) + 1)*> is Relation-like Function-like set
K75(14,0,<*((card D) + 1)*>) is set
Load (goto ((card D) + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,(goto ((card D) + 1))) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
{0} is V1() functional set
K376({0},(goto ((card D) + 1))) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(goto ((card D) + 1))} -valued Function-like constant V23({0}) V27({0},{(goto ((card D) + 1))}) Element of K6(K7({0},{(goto ((card D) + 1))}))
{(goto ((card D) + 1))} is V1() set
K7({0},{(goto ((card D) + 1))}) is Relation-like set
K6(K7({0},{(goto ((card D) + 1))})) is set
A ';' (Load (goto ((card D) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(A ';' (Load (goto ((card D) + 1)))) ';' D is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((i1,i2) <=0_goto ((card A) + 2)) ';' A is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((i1,i2) <=0_goto ((card A) + 2)) ';' A) ';' (Goto ((card D) + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((((i1,i2) <=0_goto ((card A) + 2)) ';' A) ';' (Goto ((card D) + 1))) ';' D is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((i1,i2) <=0_goto ((card A) + 2)) ';' (A ';' (Goto ((card D) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((i1,i2) <=0_goto ((card A) + 2)) ';' (A ';' (Goto ((card D) + 1)))) ';' D is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
i5 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() shiftable V160() set
((i1,i2) <=0_goto ((card A) + 2)) ';' i5 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Load ((i1,i2) <=0_goto ((card A) + 2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,((i1,i2) <=0_goto ((card A) + 2))) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},((i1,i2) <=0_goto ((card A) + 2))) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {((i1,i2) <=0_goto ((card A) + 2))} -valued Function-like constant V23({0}) V27({0},{((i1,i2) <=0_goto ((card A) + 2))}) Element of K6(K7({0},{((i1,i2) <=0_goto ((card A) + 2))}))
{((i1,i2) <=0_goto ((card A) + 2))} is V1() set
K7({0},{((i1,i2) <=0_goto ((card A) + 2))}) is Relation-like set
K6(K7({0},{((i1,i2) <=0_goto ((card A) + 2))})) is set
(Load ((i1,i2) <=0_goto ((card A) + 2))) ';' i5 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
A is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
D is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i1 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
IExec (i1,A,D) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
i2 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() shiftable V160() set
i3 is Int-like Element of the U1 of SCMPDS
D . i3 is V11() V12() ext-real integer set
i4 is Int-like Element of the U1 of SCMPDS
(IExec (i1,A,D)) . i4 is V11() V12() ext-real integer set
i5 is V11() V12() ext-real integer set
DataLoc ((D . i3),i5) is Int-like Element of the U1 of SCMPDS
(D . i3) + i5 is V11() V12() ext-real integer set
K155(((D . i3) + i5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((D . i3) + i5))] is set
{1,K155(((D . i3) + i5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((D . i3) + i5))},{1}} is V1() V56() V57() set
D . (DataLoc ((D . i3),i5)) is V11() V12() ext-real integer set
if>0 (i3,i5,i1,i2) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() shiftable V160() set
IExec ((if>0 (i3,i5,i1,i2)),A,D) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (i3,i5,i1,i2)),A,D)) . i4 is V11() V12() ext-real integer set
card i1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom i1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card i2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom i2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card i1) + (card i2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card i1) + (card i2)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Start-At ((((card i1) + (card i2)) + 2),SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() ((card i1) + (card i2)) + 2 -started V160() set
K385((IC ),(((card i1) + (card i2)) + 2)) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() set
{(IC )} is V1() set
K376({(IC )},(((card i1) + (card i2)) + 2)) is V1() Relation-like non-empty non empty-yielding {(IC )} -defined NAT -valued RAT -valued INT -valued {(((card i1) + (card i2)) + 2)} -valued Function-like constant V23({(IC )}) V27({(IC )},{(((card i1) + (card i2)) + 2)}) V33() V34() V35() V36() Element of K6(K7({(IC )},{(((card i1) + (card i2)) + 2)}))
{(((card i1) + (card i2)) + 2)} is V1() V56() V57() set
K7({(IC )},{(((card i1) + (card i2)) + 2)}) is Relation-like set
K6(K7({(IC )},{(((card i1) + (card i2)) + 2)})) is set
dom (Start-At ((((card i1) + (card i2)) + 2),SCMPDS)) is V1() set
(IExec (i1,A,D)) +* (Start-At ((((card i1) + (card i2)) + 2),SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) ((card i1) + (card i2)) + 2 -started set
i1 is Int-like Element of the U1 of SCMPDS
i2 is V11() V12() ext-real integer set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
while>0 (i1,i2,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card i3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom i3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card i3) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(i1,i2) <=0_goto ((card i3) + 2) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*i1,i2,((card i3) + 2)*> is set
K75(5,0,<*i1,i2,((card i3) + 2)*>) is set
(card i3) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
- ((card i3) + 1) is V11() V12() ext-real non positive integer set
goto (- ((card i3) + 1)) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*(- ((card i3) + 1))*> is Relation-like Function-like set
K75(14,0,<*(- ((card i3) + 1))*>) is set
i3 ';' (goto (- ((card i3) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((i1,i2) <=0_goto ((card i3) + 2)) ';' (i3 ';' (goto (- ((card i3) + 1)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((i1,i2) <=0_goto ((card i3) + 2)) ';' i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((i1,i2) <=0_goto ((card i3) + 2)) ';' i3) ';' (goto (- ((card i3) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
i1 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Shift (i1,1) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V160() set
i2 is Int-like Element of the U1 of SCMPDS
i3 is V11() V12() ext-real integer set
while>0 (i2,i3,i1) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card i1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom i1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card i1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(i2,i3) <=0_goto ((card i1) + 2) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*i2,i3,((card i1) + 2)*> is set
K75(5,0,<*i2,i3,((card i1) + 2)*>) is set
(card i1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
- ((card i1) + 1) is V11() V12() ext-real non positive integer set
goto (- ((card i1) + 1)) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*(- ((card i1) + 1))*> is Relation-like Function-like set
K75(14,0,<*(- ((card i1) + 1))*>) is set
((i2,i3) <=0_goto ((card i1) + 2)) ';' i1 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((i2,i3) <=0_goto ((card i1) + 2)) ';' i1) ';' (goto (- ((card i1) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Load (goto (- ((card i1) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,(goto (- ((card i1) + 1)))) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
{0} is V1() functional set
K376({0},(goto (- ((card i1) + 1)))) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(goto (- ((card i1) + 1)))} -valued Function-like constant V23({0}) V27({0},{(goto (- ((card i1) + 1)))}) Element of K6(K7({0},{(goto (- ((card i1) + 1)))}))
{(goto (- ((card i1) + 1)))} is V1() set
K7({0},{(goto (- ((card i1) + 1)))}) is Relation-like set
K6(K7({0},{(goto (- ((card i1) + 1)))})) is set
(((i2,i3) <=0_goto ((card i1) + 2)) ';' i1) ';' (Load (goto (- ((card i1) + 1)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Load ((i2,i3) <=0_goto ((card i1) + 2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,((i2,i3) <=0_goto ((card i1) + 2))) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},((i2,i3) <=0_goto ((card i1) + 2))) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {((i2,i3) <=0_goto ((card i1) + 2))} -valued Function-like constant V23({0}) V27({0},{((i2,i3) <=0_goto ((card i1) + 2))}) Element of K6(K7({0},{((i2,i3) <=0_goto ((card i1) + 2))}))
{((i2,i3) <=0_goto ((card i1) + 2))} is V1() set
K7({0},{((i2,i3) <=0_goto ((card i1) + 2))}) is Relation-like set
K6(K7({0},{((i2,i3) <=0_goto ((card i1) + 2))})) is set
(Load ((i2,i3) <=0_goto ((card i1) + 2))) ';' i1 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((Load ((i2,i3) <=0_goto ((card i1) + 2))) ';' i1) ';' (Load (goto (- ((card i1) + 1)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card (Load ((i2,i3) <=0_goto ((card i1) + 2))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (Load ((i2,i3) <=0_goto ((card i1) + 2))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
{0} is V1() functional set
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
i2 +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart i3 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
Data-Locations is Element of K6( the U1 of SCMPDS)
K6( the U1 of SCMPDS) is set
i3 | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
Initialize i3 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i4 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
stop i4 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
i4 ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
i1 +* (stop i4) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
LifeSpan ((i1 +* (stop i4)),(Initialize i2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
IExec (i4,i1,(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart (IExec (i4,i1,(Initialize i2))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(IExec (i4,i1,(Initialize i2))) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
i5 is Int-like Element of the U1 of SCMPDS
i2 . i5 is V11() V12() ext-real integer set
i6 is V11() V12() ext-real integer set
DataLoc ((i2 . i5),i6) is Int-like Element of the U1 of SCMPDS
(i2 . i5) + i6 is V11() V12() ext-real integer set
K155(((i2 . i5) + i6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((i2 . i5) + i6))] is set
{1,K155(((i2 . i5) + i6))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((i2 . i5) + i6))},{1}} is V1() V56() V57() set
i2 . (DataLoc ((i2 . i5),i6)) is V11() V12() ext-real integer set
while>0 (i5,i6,i4) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
stop (while>0 (i5,i6,i4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
(while>0 (i5,i6,i4)) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
i1 +* (stop (while>0 (i5,i6,i4))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),i7) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
card i4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom i4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card i4) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(i5,i6) <=0_goto ((card i4) + 2) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*i5,i6,((card i4) + 2)*> is set
K75(5,0,<*i5,i6,((card i4) + 2)*>) is set
(card i4) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
- ((card i4) + 1) is V11() V12() ext-real non positive integer set
goto (- ((card i4) + 1)) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*(- ((card i4) + 1))*> is Relation-like Function-like set
K75(14,0,<*(- ((card i4) + 1))*>) is set
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Shift (i4,1) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V160() set
i4 ';' (goto (- ((card i4) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
((i5,i6) <=0_goto ((card i4) + 2)) ';' (i4 ';' (goto (- ((card i4) + 1)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),(0 + 1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Following ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0))) is Element of the InstructionsF of SCMPDS
IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0)) . (IC ) is set
K72( the InstructionsF of SCMPDS,(i1 +* (stop (while>0 (i5,i6,i4)))),(IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0)))) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . (CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0)))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0))))) . (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),0)) is set
Following ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2)) is Element of the InstructionsF of SCMPDS
IC (Initialize i2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize i2) . (IC ) is set
K72( the InstructionsF of SCMPDS,(i1 +* (stop (while>0 (i5,i6,i4)))),(IC (Initialize i2))) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2))),(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2)))) . (Initialize i2) is set
Exec (((i5,i6) <=0_goto ((card i4) + 2)),(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((i5,i6) <=0_goto ((card i4) + 2)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((i5,i6) <=0_goto ((card i4) + 2))) . (Initialize i2) is set
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)),(LifeSpan ((i1 +* (stop i4)),(Initialize i2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
dom (Start-At (0,SCMPDS)) is V1() set
(Initialize i2) . i5 is V11() V12() ext-real integer set
DataLoc (((Initialize i2) . i5),i6) is Int-like Element of the U1 of SCMPDS
((Initialize i2) . i5) + i6 is V11() V12() ext-real integer set
K155((((Initialize i2) . i5) + i6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize i2) . i5) + i6))] is set
{1,K155((((Initialize i2) . i5) + i6))} is V1() set
{{1,K155((((Initialize i2) . i5) + i6))},{1}} is V1() V56() V57() set
(Initialize i2) . (DataLoc (((Initialize i2) . i5),i6)) is V11() V12() ext-real integer set
(Initialize i2) . (DataLoc ((i2 . i5),i6)) is V11() V12() ext-real integer set
(LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),(((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1) + 1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
dom (while>0 (i5,i6,i4)) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
k7 is Int-like Element of the U1 of SCMPDS
(Initialize i2) . k7 is V11() V12() ext-real integer set
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)) . k7 is V11() V12() ext-real integer set
DataPart (Initialize i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(Initialize i2) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
DataPart (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
(i1 +* (stop i4)) +* (stop i4) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize i2) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)) . (IC ) is set
succ 0 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((i1 +* (stop i4)),(Initialize i2),(LifeSpan ((i1 +* (stop i4)),(Initialize i2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart (Comput ((i1 +* (stop i4)),(Initialize i2),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(Comput ((i1 +* (stop i4)),(Initialize i2),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
DataPart (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
Result ((i1 +* (stop i4)),(Initialize i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart (Result ((i1 +* (stop i4)),(Initialize i2))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(Result ((i1 +* (stop i4)),(Initialize i2))) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) . (IC ) is set
CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1)))) is Element of the InstructionsF of SCMPDS
IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))) . (IC ) is set
K72( the InstructionsF of SCMPDS,(i1 +* (stop (while>0 (i5,i6,i4)))),(IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))))) is Element of the InstructionsF of SCMPDS
(i1 +* (stop (while>0 (i5,i6,i4)))) . ((card i4) + 1) is Element of the InstructionsF of SCMPDS
(while>0 (i5,i6,i4)) . ((card i4) + 1) is set
Following ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec ((CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (CurInstr ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1)))))) . (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))) is set
Exec ((goto (- ((card i4) + 1))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (goto (- ((card i4) + 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (goto (- ((card i4) + 1)))) . (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))) is set
k7 is Int-like Element of the U1 of SCMPDS
i3 . k7 is V11() V12() ext-real integer set
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))) . k7 is V11() V12() ext-real integer set
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),1)),(LifeSpan ((i1 +* (stop i4)),(Initialize i2))))) . k7 is V11() V12() ext-real integer set
IC (Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),(((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),(((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1) + 1))) . (IC ) is set
0 - ((card i4) + 1) is V1() V11() V12() ext-real non positive negative integer set
ICplusConst ((Comput ((i1 +* (stop (while>0 (i5,i6,i4)))),(Initialize i2),((LifeSpan ((i1 +* (stop i4)),(Initialize i2))) + 1))),(0 - ((card i4) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
Data-Locations is Element of K6( the U1 of SCMPDS)
K6( the U1 of SCMPDS) is set
i2 | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
stop i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
{0} is V1() functional set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
i3 ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Initialize i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
i2 +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i1 +* (stop i3) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
dom (stop i3) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
i7 is Int-like Element of the U1 of SCMPDS
i2 . i7 is V11() V12() ext-real integer set
(Initialize i2) . i7 is V11() V12() ext-real integer set
dom (Start-At (0,SCMPDS)) is V1() set
i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((i1 +* (stop i3)),(Initialize i2),i7) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((i1 +* (stop i3)),(Initialize i2),i7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop i3)),(Initialize i2),i7)) . (IC ) is set
i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
Comput ((i1 +* (stop i3)),(Initialize i2),i7) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((i1 +* (stop i3)),(Initialize i2),i7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop i3)),(Initialize i2),i7)) . (IC ) is set
IF1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((i1 +* (stop i3)),(Initialize i2),IF1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop i3)),(Initialize i2),IF1)) . (IC ) is set
succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() set
(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))) --> ((goto 1),(goto (- 1))) is V1() Relation-like {(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))} -defined the InstructionsF of SCMPDS -valued Function-like V27({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))}, the InstructionsF of SCMPDS) Element of K6(K7({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))}, the InstructionsF of SCMPDS))
{(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))} is V1() set
K7({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))}, the InstructionsF of SCMPDS) is Relation-like set
K6(K7({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))}, the InstructionsF of SCMPDS)) is set
K385((IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(goto 1)) is V1() V2() Relation-like NAT -defined {(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
{(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))} is V1() set
K376({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))},(goto 1)) is V1() Relation-like {(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))} -defined the InstructionsF of SCMPDS -valued {(goto 1)} -valued Function-like constant V23({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))}) V27({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))},{(goto 1)}) Element of K6(K7({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))},{(goto 1)}))
{(goto 1)} is V1() set
K7({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))},{(goto 1)}) is Relation-like set
K6(K7({(IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))},{(goto 1)})) is set
K385((succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))),(goto (- 1))) is V1() V2() Relation-like {(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
{(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))} is V1() V56() V57() set
K376({(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))},(goto (- 1))) is V1() Relation-like {(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))} -defined the InstructionsF of SCMPDS -valued {(goto (- 1))} -valued Function-like constant V23({(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))}) V27({(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))},{(goto (- 1))}) Element of K6(K7({(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))},{(goto (- 1))}))
{(goto (- 1))} is V1() set
K7({(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))},{(goto (- 1))}) is Relation-like set
K6(K7({(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))},{(goto (- 1))})) is set
K385((IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(goto 1)) +* K385((succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))),(goto (- 1))) is V1() Relation-like the InstructionsF of SCMPDS -valued Function-like set
(i1 +* (stop i3)) +* (((IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))))) --> ((goto 1),(goto (- 1)))) is V1() Relation-like the InstructionsF of SCMPDS -valued Function-like set
(i1 +* (stop i3)) +* ((IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1))),(goto 1)) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j4 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j4 +* ((succ (IC (Comput ((i1 +* (stop i3)),(Initialize i2),IF1)))),(goto (- 1))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j2 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j5 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((i1 +* (stop i3)),(Initialize i2),j6) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((i1 +* (stop i3)),(Initialize i2),j6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop i3)),(Initialize i2),j6)) . (IC ) is set
Comput (j2,(Initialize i2),IF1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart (Initialize i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(Initialize i2) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
j2 +* (stop i3) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize i2) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i1 is Element of the InstructionsF of SCMPDS
i2 is Element of the InstructionsF of SCMPDS
i1 ';' i2 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
i3 is Element of the InstructionsF of SCMPDS
(i1 ';' i2) ';' i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
i4 is Element of the InstructionsF of SCMPDS
((i1 ';' i2) ';' i3) ';' i4 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card (((i1 ';' i2) ';' i3) ';' i4) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((i1 ';' i2) ';' i3) ';' i4) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card ((i1 ';' i2) ';' i3) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((i1 ';' i2) ';' i3) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((i1 ';' i2) ';' i3)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (i1 ';' i2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (i1 ';' i2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (i1 ';' i2)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card (i1 ';' i2)) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
IExec (i3,i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (IExec (i3,i1,i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
{0} is V1() functional set
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec (i3,i1,i2)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i4 is Int-like Element of the U1 of SCMPDS
i2 . i4 is V11() V12() ext-real integer set
i5 is Int-like Element of the U1 of SCMPDS
i2 . i5 is V11() V12() ext-real integer set
i6 is Int-like Element of the U1 of SCMPDS
i2 . i6 is V11() V12() ext-real integer set
IF1 is V11() V12() ext-real integer set
i7 is V11() V12() ext-real integer set
DataLoc ((i2 . i4),i7) is Int-like Element of the U1 of SCMPDS
(i2 . i4) + i7 is V11() V12() ext-real integer set
K155(((i2 . i4) + i7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((i2 . i4) + i7))] is set
{1,K155(((i2 . i4) + i7))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((i2 . i4) + i7))},{1}} is V1() V56() V57() set
i2 . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
IF1 + (i2 . (DataLoc ((i2 . i4),i7))) is V11() V12() ext-real integer set
while>0 (i4,i7,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
IExec ((while>0 (i4,i7,i3)),i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((while>0 (i4,i7,i3)),i1,(Initialize (IExec (i3,i1,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
{i5} is V1() set
WH1 is Int-like Element of the U1 of SCMPDS
i2 . WH1 is V11() V12() ext-real integer set
WH1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
WH1 . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
IF1 + (WH1 . (DataLoc ((i2 . i4),i7))) is V11() V12() ext-real integer set
{i6} is V1() set
WH1 . i4 is V11() V12() ext-real integer set
WH1 . i6 is V11() V12() ext-real integer set
WH1 . i5 is V11() V12() ext-real integer set
j1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (i3,j1,WH1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (i3,j1,WH1)) . i4 is V11() V12() ext-real integer set
(IExec (i3,j1,WH1)) . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
j2 is Int-like Element of the U1 of SCMPDS
IF1 + ((IExec (i3,j1,WH1)) . (DataLoc ((i2 . i4),i7))) is V11() V12() ext-real integer set
(IExec (i3,j1,WH1)) . i5 is V11() V12() ext-real integer set
(IExec (i3,j1,WH1)) . j2 is V11() V12() ext-real integer set
j2 is Int-like Element of the U1 of SCMPDS
(IExec (i3,j1,WH1)) . j2 is V11() V12() ext-real integer set
(IExec (i3,j1,WH1)) . i6 is V11() V12() ext-real integer set
WH1 . j2 is V11() V12() ext-real integer set
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
IExec (i3,i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (IExec (i3,i1,i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
{0} is V1() functional set
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec (i3,i1,i2)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i5 is Int-like Element of the U1 of SCMPDS
i2 . i5 is V11() V12() ext-real integer set
i6 is Int-like Element of the U1 of SCMPDS
i2 . i6 is V11() V12() ext-real integer set
i4 is Int-like Element of the U1 of SCMPDS
i2 . i4 is V11() V12() ext-real integer set
IF1 is V11() V12() ext-real integer set
i7 is V11() V12() ext-real integer set
DataLoc ((i2 . i4),i7) is Int-like Element of the U1 of SCMPDS
(i2 . i4) + i7 is V11() V12() ext-real integer set
K155(((i2 . i4) + i7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((i2 . i4) + i7))] is set
{1,K155(((i2 . i4) + i7))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((i2 . i4) + i7))},{1}} is V1() V56() V57() set
while>0 (i4,i7,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
i2 . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
IExec ((while>0 (i4,i7,i3)),i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((while>0 (i4,i7,i3)),i1,(Initialize (IExec (i3,i1,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
WH1 is Relation-like product (the_Values_of SCMPDS) -defined NAT -valued Function-like V27( product (the_Values_of SCMPDS), NAT ) V33() V34() V35() V36() Element of K6(K7((product (the_Values_of SCMPDS)),NAT))
j2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j2 . i5 is V11() V12() ext-real integer set
j2 . i6 is V11() V12() ext-real integer set
WH1 . j1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j1 . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
j1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j1 . i4 is V11() V12() ext-real integer set
j1 . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
j2 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (i3,j2,j1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (IExec (i3,j2,j1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (i3,j2,j1)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (i3,j2,j1)) . i4 is V11() V12() ext-real integer set
j5 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j5 . i5 is V11() V12() ext-real integer set
j5 . i6 is V11() V12() ext-real integer set
WH1 . j1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH1 . (Initialize (IExec (i3,j2,j1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize (IExec (i3,j2,j1))) . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
(IExec (i3,j2,j1)) . (DataLoc ((i2 . i4),i7)) is V11() V12() ext-real integer set
j5 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j5 . i5 is V11() V12() ext-real integer set
j5 . i6 is V11() V12() ext-real integer set
j5 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j5 . i5 is V11() V12() ext-real integer set
j5 . i6 is V11() V12() ext-real integer set
(IExec (i3,j2,j1)) . i5 is V11() V12() ext-real integer set
j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j6 . i5 is V11() V12() ext-real integer set
j6 . i6 is V11() V12() ext-real integer set
(IExec (i3,j2,j1)) . i6 is V11() V12() ext-real integer set
j1 . i6 is V11() V12() ext-real integer set
j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j6 . i5 is V11() V12() ext-real integer set
j6 . i6 is V11() V12() ext-real integer set
j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j6 . i5 is V11() V12() ext-real integer set
j6 . i6 is V11() V12() ext-real integer set
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
IExec (i3,i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (IExec (i3,i1,i2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
{0} is V1() functional set
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec (i3,i1,i2)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IF1 is Int-like Element of the U1 of SCMPDS
i2 . IF1 is V11() V12() ext-real integer set
i7 is Int-like Element of the U1 of SCMPDS
i2 . i7 is V11() V12() ext-real integer set
i5 is Int-like Element of the U1 of SCMPDS
i2 . i5 is V11() V12() ext-real integer set
i6 is Int-like Element of the U1 of SCMPDS
i2 . i6 is V11() V12() ext-real integer set
i4 is Int-like Element of the U1 of SCMPDS
i2 . i4 is V11() V12() ext-real integer set
WH1 is V11() V12() ext-real integer set
(i2 . i7) - WH1 is V11() V12() ext-real integer set
((i2 . i7) - WH1) + (i2 . i5) is V11() V12() ext-real integer set
j1 is V11() V12() ext-real integer set
WB1 is V11() V12() ext-real integer set
DataLoc ((i2 . i4),WB1) is Int-like Element of the U1 of SCMPDS
(i2 . i4) + WB1 is V11() V12() ext-real integer set
K155(((i2 . i4) + WB1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((i2 . i4) + WB1))] is set
{1,K155(((i2 . i4) + WB1))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((i2 . i4) + WB1))},{1}} is V1() V56() V57() set
while>0 (i4,WB1,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
i2 . (DataLoc ((i2 . i4),WB1)) is V11() V12() ext-real integer set
IExec ((while>0 (i4,WB1,i3)),i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((while>0 (i4,WB1,i3)),i1,(Initialize (IExec (i3,i1,i2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j3 is Relation-like product (the_Values_of SCMPDS) -defined NAT -valued Function-like V27( product (the_Values_of SCMPDS), NAT ) V33() V34() V35() V36() Element of K6(K7((product (the_Values_of SCMPDS)),NAT))
j5 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j4 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j5 . IF1 is V11() V12() ext-real integer set
j5 . i7 is V11() V12() ext-real integer set
(j5 . i7) - WH1 is V11() V12() ext-real integer set
j5 . i5 is V11() V12() ext-real integer set
((j5 . i7) - WH1) + (j5 . i5) is V11() V12() ext-real integer set
j5 . i6 is V11() V12() ext-real integer set
j3 . j4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j4 . (DataLoc ((i2 . i4),WB1)) is V11() V12() ext-real integer set
j4 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j4 . i4 is V11() V12() ext-real integer set
j4 . (DataLoc ((i2 . i4),WB1)) is V11() V12() ext-real integer set
j5 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (i3,j5,j4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (IExec (i3,j5,j4)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (i3,j5,j4)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IF2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IF2 . IF1 is V11() V12() ext-real integer set
IF2 . i7 is V11() V12() ext-real integer set
(IF2 . i7) - WH1 is V11() V12() ext-real integer set
IF2 . i5 is V11() V12() ext-real integer set
((IF2 . i7) - WH1) + (IF2 . i5) is V11() V12() ext-real integer set
IF2 . i6 is V11() V12() ext-real integer set
IF2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IF2 . IF1 is V11() V12() ext-real integer set
IF2 . i7 is V11() V12() ext-real integer set
(IF2 . i7) - WH1 is V11() V12() ext-real integer set
IF2 . i5 is V11() V12() ext-real integer set
((IF2 . i7) - WH1) + (IF2 . i5) is V11() V12() ext-real integer set
IF2 . i6 is V11() V12() ext-real integer set
j4 . i6 is V11() V12() ext-real integer set
j4 . IF1 is V11() V12() ext-real integer set
j4 . i7 is V11() V12() ext-real integer set
(j4 . i7) - WH1 is V11() V12() ext-real integer set
j4 . i5 is V11() V12() ext-real integer set
((j4 . i7) - WH1) + (j4 . i5) is V11() V12() ext-real integer set
(IExec (i3,j5,j4)) . i4 is V11() V12() ext-real integer set
j3 . j4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j3 . (Initialize (IExec (i3,j5,j4))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize (IExec (i3,j5,j4))) . (DataLoc ((i2 . i4),WB1)) is V11() V12() ext-real integer set
(IExec (i3,j5,j4)) . (DataLoc ((i2 . i4),WB1)) is V11() V12() ext-real integer set
WB2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
WB2 . IF1 is V11() V12() ext-real integer set
WB2 . i7 is V11() V12() ext-real integer set
(WB2 . i7) - WH1 is V11() V12() ext-real integer set
WB2 . i5 is V11() V12() ext-real integer set
((WB2 . i7) - WH1) + (WB2 . i5) is V11() V12() ext-real integer set
WB2 . i6 is V11() V12() ext-real integer set
(IExec (i3,j5,j4)) . IF1 is V11() V12() ext-real integer set
(IExec (i3,j5,j4)) . i7 is V11() V12() ext-real integer set
((IExec (i3,j5,j4)) . i7) - WH1 is V11() V12() ext-real integer set
(IExec (i3,j5,j4)) . i5 is V11() V12() ext-real integer set
(((IExec (i3,j5,j4)) . i7) - WH1) + ((IExec (i3,j5,j4)) . i5) is V11() V12() ext-real integer set
((WB2 . i7) - WH1) + ((IExec (i3,j5,j4)) . i5) is V11() V12() ext-real integer set
(IExec (i3,j5,j4)) . i6 is V11() V12() ext-real integer set
i1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
i3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i4 - 1 is V11() V12() ext-real integer set
i2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i4 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i1 . i4 is V11() V12() ext-real integer set
i6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 . i6 is V11() V12() ext-real integer set
i1 . i7 is V11() V12() ext-real integer set
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
i4 is Int-like Element of the U1 of SCMPDS
i2 . i4 is V11() V12() ext-real integer set
i6 is V11() V12() ext-real integer set
i5 is V11() V12() ext-real integer set
while>0 (i4,i5,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
IExec ((while>0 (i4,i5,i3)),i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataLoc (i6,i5) is Int-like Element of the U1 of SCMPDS
i6 + i5 is V11() V12() ext-real integer set
K155((i6 + i5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((i6 + i5))] is set
{1,K155((i6 + i5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((i6 + i5))},{1}} is V1() V56() V57() set
i2 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
i7 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IF1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len IF1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + WH1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
WB1 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos j1 is Int-like Element of the U1 of SCMPDS
K397(j1) is Int-like Element of the U1 of K388()
i2 . (intpos j1) is V11() V12() ext-real integer set
j1 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (j1 + 1) is Int-like Element of the U1 of SCMPDS
K397((j1 + 1)) is Int-like Element of the U1 of K388()
i2 . (intpos (j1 + 1)) is V11() V12() ext-real integer set
Initialize i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
{0} is V1() functional set
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
i2 +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (while>0 (i4,i5,i3)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (i4,i5,i3)) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
2 * 0 is V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() Element of NAT
(WB1 + WH1) + (2 * 0) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((WB1 + WH1) + (2 * 0)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
j5 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j5 . i4 is V11() V12() ext-real integer set
j5 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(j5 . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
j6 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j6 +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j7 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len j7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IF2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
2 * IF2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(2 * IF2) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + (2 * IF2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((WB1 + WH1) + (2 * IF2)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
WH2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + WH2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WB2 is Int-like Element of the U1 of SCMPDS
K397(WB2) is Int-like Element of the U1 of K388()
j5 . (intpos WB2) is V11() V12() ext-real integer set
WB1 + k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB2 + 1) is Int-like Element of the U1 of SCMPDS
K397((WB2 + 1)) is Int-like Element of the U1 of K388()
j5 . (intpos (WB2 + 1)) is V11() V12() ext-real integer set
k1 - WH2 is V11() V12() ext-real integer set
Initialize j5 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j5 +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
i3 ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
j6 +* (stop i3) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
LifeSpan ((j6 +* (stop i3)),j5) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(LifeSpan ((j6 +* (stop i3)),j5)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) . i4 is V11() V12() ext-real integer set
DataPart (Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
Data-Locations is Element of K6( the U1 of SCMPDS)
K6( the U1 of SCMPDS) is set
(Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
IExec (i3,j6,j5) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataPart (IExec (i3,j6,j5)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(IExec (i3,j6,j5)) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
k4 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len k4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k4 . K4 is V11() V12() ext-real integer set
WB1 + K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + K4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + K4)) is Int-like Element of the U1 of K388()
(IExec (i3,j6,j5)) . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
(Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k4 . K4 is V11() V12() ext-real integer set
WB1 + K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + K4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + K4)) is Int-like Element of the U1 of K388()
j5 . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k4 . K4 is V11() V12() ext-real integer set
WB1 + K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + K4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + K4)) is Int-like Element of the U1 of K388()
(IExec (i3,j6,j5)) . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
j5 . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((WB1 + WH1) + K4) is Int-like Element of the U1 of SCMPDS
K397(((WB1 + WH1) + K4)) is Int-like Element of the U1 of K388()
(Comput ((j6 +* (stop (while>0 (i4,i5,i3)))),j5,k2)) . (intpos ((WB1 + WH1) + K4)) is V11() V12() ext-real integer set
(IExec (i3,j6,j5)) . (intpos ((WB1 + WH1) + K4)) is V11() V12() ext-real integer set
j5 . (intpos ((WB1 + WH1) + K4)) is V11() V12() ext-real integer set
(IExec (i3,j6,j5)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(2 * IF2) - 1 is V11() V12() ext-real integer set
K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + K4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + K4)) is Int-like Element of the U1 of K388()
(IExec (i3,j6,j5)) . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
j5 . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
(IExec (i3,j6,j5)) . i4 is V11() V12() ext-real integer set
j5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j5 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j6 . i4 is V11() V12() ext-real integer set
j6 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(j6 . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
j7 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j7 +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IF2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len IF2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
2 * WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(2 * WB2) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
WH2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + (2 * WB2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((WB1 + WH1) + (2 * WB2)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH2 is Int-like Element of the U1 of SCMPDS
K397(WH2) is Int-like Element of the U1 of K388()
j6 . (intpos WH2) is V11() V12() ext-real integer set
WB1 + k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WH2 + 1) is Int-like Element of the U1 of SCMPDS
K397((WH2 + 1)) is Int-like Element of the U1 of K388()
j6 . (intpos (WH2 + 1)) is V11() V12() ext-real integer set
k2 - k1 is V11() V12() ext-real integer set
Initialize j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j6 +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
i3 ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
j7 +* (stop i3) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
LifeSpan ((j7 +* (stop i3)),j6) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(LifeSpan ((j7 +* (stop i3)),j6)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
k1 - 1 is V11() V12() ext-real integer set
(k2 - k1) - 1 is V11() V12() ext-real integer set
(j5 + 1) - 1 is V11() V12() ext-real integer set
k1 + (j5 + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k7 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len k7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IExec (i3,j7,j6) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (i3,j7,j6)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(2 * WB2) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec (i3,j7,j6)) . (intpos WH2) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . (intpos (WH2 + 1)) is V11() V12() ext-real integer set
WH2 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WH2 + 2) is Int-like Element of the U1 of SCMPDS
K397((WH2 + 2)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WH2 + 2)) is V11() V12() ext-real integer set
WH2 + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WH2 + 3) is Int-like Element of the U1 of SCMPDS
K397((WH2 + 3)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WH2 + 3)) is V11() V12() ext-real integer set
k9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + k9) is Int-like Element of the U1 of SCMPDS
K397((WB1 + k9)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
j6 . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
k9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + k9) - 1 is V11() V12() ext-real integer set
(WB1 + k9) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB1 + k9) is Int-like Element of the U1 of SCMPDS
K397((WB1 + k9)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
k9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + k9) - 1 is V11() V12() ext-real integer set
(WB1 + k9) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB1 + k9) is Int-like Element of the U1 of SCMPDS
K397((WB1 + k9)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
DataPart (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
Data-Locations is Element of K6( the U1 of SCMPDS)
K6( the U1 of SCMPDS) is set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
DataPart (IExec (i3,j7,j6)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
(IExec (i3,j7,j6)) | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
k0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + k0) - 1 is V11() V12() ext-real integer set
(WB1 + k0) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB1 + k0) is Int-like Element of the U1 of SCMPDS
K397((WB1 + k0)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WB1 + k0)) is V11() V12() ext-real integer set
k9 - 1 is V11() V12() ext-real integer set
k0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 * (WB2 + 1) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(2 * (WB2 + 1)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
IF3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + IF3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + IF3) - 1 is V11() V12() ext-real integer set
(WB1 + IF3) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB1 + IF3) is Int-like Element of the U1 of SCMPDS
K397((WB1 + IF3)) is Int-like Element of the U1 of K388()
(IExec (i3,j7,j6)) . (intpos (WB1 + IF3)) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . i4 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . i4 is V11() V12() ext-real integer set
(WB1 + WH1) + (2 * (WB2 + 1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((WB1 + WH1) + (2 * (WB2 + 1))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k9 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((WB1 + WH1) + (2 * (WB2 + 1))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((((WB1 + WH1) + (2 * (WB2 + 1))) + 1) + 1) is Int-like Element of the U1 of SCMPDS
K397(((((WB1 + WH1) + (2 * (WB2 + 1))) + 1) + 1)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos ((((WB1 + WH1) + (2 * (WB2 + 1))) + 1) + 1)) is V11() V12() ext-real integer set
1 + j5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k1 + (1 + j5) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k9 + (1 + j5) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(k9 + 1) + j5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k2 - (k9 + 1) is V11() V12() ext-real integer set
intpos (((WB1 + WH1) + (2 * (WB2 + 1))) + 1) is Int-like Element of the U1 of SCMPDS
K397((((WB1 + WH1) + (2 * (WB2 + 1))) + 1)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (((WB1 + WH1) + (2 * (WB2 + 1))) + 1)) is V11() V12() ext-real integer set
WB1 + (k9 + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . i4 is V11() V12() ext-real integer set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (intpos (((WB1 + WH1) + (2 * (WB2 + 1))) + 1)) is V11() V12() ext-real integer set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (intpos ((((WB1 + WH1) + (2 * (WB2 + 1))) + 1) + 1)) is V11() V12() ext-real integer set
WH3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k7 . WH3 is V11() V12() ext-real integer set
WB1 + WH3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + WH3) is Int-like Element of the U1 of SCMPDS
K397((WB1 + WH3)) is Int-like Element of the U1 of K388()
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (intpos (WB1 + WH3)) is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + WH3)) is V11() V12() ext-real integer set
(j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
((Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
WH3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j8 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len j8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . i4 is V11() V12() ext-real integer set
j9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . j9 is V11() V12() ext-real integer set
WB1 + j9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + j9) is Int-like Element of the U1 of SCMPDS
K397((WB1 + j9)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + j9)) is V11() V12() ext-real integer set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (intpos (WB1 + j9)) is V11() V12() ext-real integer set
j9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . j9 is V11() V12() ext-real integer set
WB1 + j9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + j9) is Int-like Element of the U1 of SCMPDS
K397((WB1 + j9)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + j9)) is V11() V12() ext-real integer set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (intpos (WB1 + j9)) is V11() V12() ext-real integer set
j9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + j9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((WB1 + WH1) + j9) is Int-like Element of the U1 of SCMPDS
K397(((WB1 + WH1) + j9)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos ((WB1 + WH1) + j9)) is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos ((WB1 + WH1) + j9)) is V11() V12() ext-real integer set
(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))) . (intpos ((WB1 + WH1) + j9)) is V11() V12() ext-real integer set
((Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos WH2) is V11() V12() ext-real integer set
(WB1 + WH1) + ((2 * WB2) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((WB1 + WH1) + ((2 * WB2) + 1)) is Int-like Element of the U1 of SCMPDS
K397(((WB1 + WH1) + ((2 * WB2) + 1))) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos ((WB1 + WH1) + ((2 * WB2) + 1))) is V11() V12() ext-real integer set
j8 . k9 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
j8 . k9 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
j8 . k9 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
j8 . k9 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + k9)) is V11() V12() ext-real integer set
a1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . a1 is V11() V12() ext-real integer set
WB1 + a1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a1) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a1)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a1)) is V11() V12() ext-real integer set
j8 . a1 is V11() V12() ext-real integer set
WB1 + a1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a1) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a1)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a1)) is V11() V12() ext-real integer set
j8 . a1 is V11() V12() ext-real integer set
WB1 + a1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a1) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a1)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a1)) is V11() V12() ext-real integer set
j8 . a1 is V11() V12() ext-real integer set
WB1 + a1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a1) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a1)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a1)) is V11() V12() ext-real integer set
k7 . a1 is V11() V12() ext-real integer set
k2 - 1 is V11() V12() ext-real integer set
k0 - k1 is V11() V12() ext-real integer set
(k2 - 1) - k1 is V11() V12() ext-real integer set
(2 * WB2) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WH2 + 1)) is V11() V12() ext-real integer set
(WB1 + WH1) + ((2 * WB2) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((WB1 + WH1) + ((2 * WB2) + 2)) is Int-like Element of the U1 of SCMPDS
K397(((WB1 + WH1) + ((2 * WB2) + 2))) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos ((WB1 + WH1) + ((2 * WB2) + 2))) is V11() V12() ext-real integer set
WB1 + k0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . i4 is V11() V12() ext-real integer set
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (intpos WH2) is V11() V12() ext-real integer set
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (intpos (WH2 + 1)) is V11() V12() ext-real integer set
a2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . a2 is V11() V12() ext-real integer set
WB1 + a2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a2) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a2)) is Int-like Element of the U1 of K388()
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (intpos (WB1 + a2)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a2)) is V11() V12() ext-real integer set
((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
((Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
a2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))),a2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Comput ((((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))),a2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))),a2)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
a3 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len a3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))),a2)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Comput ((((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))),a2)) . i4 is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((WB1 + WH1) + a4) is Int-like Element of the U1 of SCMPDS
K397(((WB1 + WH1) + a4)) is Int-like Element of the U1 of K388()
(Comput ((((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))),a2)) . (intpos ((WB1 + WH1) + a4)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos ((WB1 + WH1) + a4)) is V11() V12() ext-real integer set
(Initialize (Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3))) . (intpos ((WB1 + WH1) + a4)) is V11() V12() ext-real integer set
((Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
1 + 0 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
j8 . a4 is V11() V12() ext-real integer set
a3 . k9 is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
j8 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
j8 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
j8 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
k7 . a4 is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . a4 is V11() V12() ext-real integer set
a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k7 . a5 is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a5) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a5)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a4 - 1 is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
a3 . a4 is V11() V12() ext-real integer set
WB1 + a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a4)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a4)) is V11() V12() ext-real integer set
j8 . a4 is V11() V12() ext-real integer set
a4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a4 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
a3 . a4 is V11() V12() ext-real integer set
a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j8 . a5 is V11() V12() ext-real integer set
WB1 + a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a5) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a5)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
WB1 + a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a5) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a5)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
WB1 + a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a5) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a5)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
WB1 + a5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a5) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a5)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . (intpos (WB1 + a5)) is V11() V12() ext-real integer set
(k1 - 1) + 1 is V11() V12() ext-real integer set
WH3 + a2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((LifeSpan ((j7 +* (stop i3)),j6)) + 2) + (WH3 + a2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
a4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,a4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,a4)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,a4)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,a4)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,a4)) . i4 is V11() V12() ext-real integer set
Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),(WH3 + a2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),(WH3 + a2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k7 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a3 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
a3 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
a3 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
a3 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
j8 . a6 is V11() V12() ext-real integer set
a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a3 . a7 is V11() V12() ext-real integer set
j8 . a7 is V11() V12() ext-real integer set
a3 . a6 is V11() V12() ext-real integer set
j8 . a6 is V11() V12() ext-real integer set
a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a3 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
j6 . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
j8 . a6 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
j8 . a6 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
j8 . a6 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
j8 . a6 is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a3 . a6 is V11() V12() ext-real integer set
WB1 + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + a6) is Int-like Element of the U1 of SCMPDS
K397((WB1 + a6)) is Int-like Element of the U1 of K388()
j6 . (intpos (WB1 + a6)) is V11() V12() ext-real integer set
a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + a6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((WB1 + WH1) + a6) is Int-like Element of the U1 of SCMPDS
K397(((WB1 + WH1) + a6)) is Int-like Element of the U1 of K388()
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,a4)) . (intpos ((WB1 + WH1) + a6)) is V11() V12() ext-real integer set
(Comput (((j7 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2)))),WH3)) . (intpos ((WB1 + WH1) + a6)) is V11() V12() ext-real integer set
(Comput ((j7 +* (stop (while>0 (i4,i5,i3)))),j6,((LifeSpan ((j7 +* (stop i3)),j6)) + 2))) . (intpos ((WB1 + WH1) + a6)) is V11() V12() ext-real integer set
(IExec (i3,j7,j6)) . (intpos ((WB1 + WH1) + a6)) is V11() V12() ext-real integer set
j6 . (intpos ((WB1 + WH1) + a6)) is V11() V12() ext-real integer set
j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j6 . i4 is V11() V12() ext-real integer set
WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
2 * WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(2 * WB2) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
j6 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
WH2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + (2 * WB2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((WB1 + WH1) + (2 * WB2)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH2 is Int-like Element of the U1 of SCMPDS
K397(WH2) is Int-like Element of the U1 of K388()
j6 . (intpos WH2) is V11() V12() ext-real integer set
WB1 + k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WH2 + 1) is Int-like Element of the U1 of SCMPDS
K397((WH2 + 1)) is Int-like Element of the U1 of K388()
j6 . (intpos (WH2 + 1)) is V11() V12() ext-real integer set
k2 - k1 is V11() V12() ext-real integer set
IF2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len IF2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j7 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j7 +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
(j6 . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
i1 +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
(2 * 0) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(i2 . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
WH1 - 1 is V11() V12() ext-real integer set
WH1 - 1 is V11() V12() ext-real integer set
j5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j6 . i4 is V11() V12() ext-real integer set
WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
2 * WB2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(2 * WB2) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
j6 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
WH2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(WB1 + WH1) + (2 * WB2) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((WB1 + WH1) + (2 * WB2)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH2 is Int-like Element of the U1 of SCMPDS
K397(WH2) is Int-like Element of the U1 of K388()
j6 . (intpos WH2) is V11() V12() ext-real integer set
WB1 + k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WH2 + 1) is Int-like Element of the U1 of SCMPDS
K397((WH2 + 1)) is Int-like Element of the U1 of K388()
j6 . (intpos (WH2 + 1)) is V11() V12() ext-real integer set
k2 - k1 is V11() V12() ext-real integer set
IF2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len IF2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
j7 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
j7 +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
(j6 . (DataLoc (i6,i5))) - 2 is V11() V12() ext-real integer set
WH1 - 1 is V11() V12() ext-real integer set
j5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j6 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len j6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) . i4 is V11() V12() ext-real integer set
j5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
j6 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len j6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
(Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)) . i4 is V11() V12() ext-real integer set
(i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))) . (IC ) is set
card i3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom i3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card i3) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(i4,i5) <=0_goto ((card i3) + 2) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*i4,i5,((card i3) + 2)*> is set
K75(5,0,<*i4,i5,((card i3) + 2)*>) is set
(card i3) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
- ((card i3) + 1) is V11() V12() ext-real non positive integer set
goto (- ((card i3) + 1)) is V94( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
<*(- ((card i3) + 1))*> is Relation-like Function-like set
K75(14,0,<*(- ((card i3) + 1))*>) is set
card (while>0 (i4,i5,i3)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (while>0 (i4,i5,i3)) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
dom (stop (while>0 (i4,i5,i3))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
dom IF1 is V139() Element of K6(NAT)
Seg WH1 is Element of K6(NAT)
((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))) . ((card i3) + 2) is Element of the InstructionsF of SCMPDS
(stop (while>0 (i4,i5,i3))) . ((card i3) + 2) is set
i3 ';' (goto (- ((card i3) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
((i4,i5) <=0_goto ((card i3) + 2)) ';' (i3 ';' (goto (- ((card i3) + 1)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),(0 + 1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Following (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0))) is Element of the InstructionsF of SCMPDS
IC (Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0)) . (IC ) is set
K72( the InstructionsF of SCMPDS,((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(IC (Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0)))) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . (CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0)))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0))))) . (Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),0)) is set
Following (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)))) is Element of the InstructionsF of SCMPDS
K72( the InstructionsF of SCMPDS,((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(IC (Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))))) is Element of the InstructionsF of SCMPDS
Exec ((CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)))))) . (Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))) is set
Exec (((i4,i5) <=0_goto ((card i3) + 2)),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((i4,i5) <=0_goto ((card i3) + 2)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((i4,i5) <=0_goto ((card i3) + 2))) . (Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))) is set
IC (Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),1)) . (IC ) is set
ICplusConst ((Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),((card i3) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
0 + ((card i3) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
CurInstr (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),1))) is Element of the InstructionsF of SCMPDS
K72( the InstructionsF of SCMPDS,((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(IC (Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),1)))) is Element of the InstructionsF of SCMPDS
j5 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,(j5 + 1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Result ((i1 +* (stop (while>0 (i4,i5,i3)))),i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
k4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB1 + K4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (WB1 + K4) is Int-like Element of the U1 of SCMPDS
K397((WB1 + K4)) is Int-like Element of the U1 of K388()
IF1 . k4 is V11() V12() ext-real integer set
(Comput (((i1 +* (stop (while>0 (i4,i5,i3)))) +* (stop (while>0 (i4,i5,i3)))),(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))),1)) . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
(Initialize (Comput ((i1 +* (stop (while>0 (i4,i5,i3)))),i2,j5))) . (intpos (WB1 + K4)) is V11() V12() ext-real integer set
j6 . k4 is V11() V12() ext-real integer set
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
i4 is Int-like Element of the U1 of SCMPDS
i2 . i4 is V11() V12() ext-real integer set
i6 is V11() V12() ext-real integer set
i5 is V11() V12() ext-real integer set
DataLoc (i6,i5) is Int-like Element of the U1 of SCMPDS
i6 + i5 is V11() V12() ext-real integer set
K155((i6 + i5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((i6 + i5))] is set
{1,K155((i6 + i5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((i6 + i5))},{1}} is V1() V56() V57() set
i2 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
while>0 (i4,i5,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
WB1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IF1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i7 + IF1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(i7 + IF1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos WB1 is Int-like Element of the U1 of SCMPDS
K397(WB1) is Int-like Element of the U1 of K388()
i2 . (intpos WB1) is V11() V12() ext-real integer set
WB1 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB1 + 1) is Int-like Element of the U1 of SCMPDS
K397((WB1 + 1)) is Int-like Element of the U1 of K388()
i2 . (intpos (WB1 + 1)) is V11() V12() ext-real integer set
j1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len j1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IExec ((while>0 (i4,i5,i3)),i1,i2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
j3 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len j3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i3 is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
i4 is Int-like Element of the U1 of SCMPDS
i2 . i4 is V11() V12() ext-real integer set
i6 is V11() V12() ext-real integer set
i5 is V11() V12() ext-real integer set
DataLoc (i6,i5) is Int-like Element of the U1 of SCMPDS
i6 + i5 is V11() V12() ext-real integer set
K155((i6 + i5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((i6 + i5))] is set
{1,K155((i6 + i5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((i6 + i5))},{1}} is V1() V56() V57() set
i2 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
while>0 (i4,i5,i3) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
WB1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IF1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i7 + IF1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(i7 + IF1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos WB1 is Int-like Element of the U1 of SCMPDS
K397(WB1) is Int-like Element of the U1 of K388()
i2 . (intpos WB1) is V11() V12() ext-real integer set
WB1 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (WB1 + 1) is Int-like Element of the U1 of SCMPDS
K397((WB1 + 1)) is Int-like Element of the U1 of K388()
i2 . (intpos (WB1 + 1)) is V11() V12() ext-real integer set
j1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
DataPart j1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
Data-Locations is Element of K6( the U1 of SCMPDS)
K6( the U1 of SCMPDS) is set
j1 | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
DataPart i2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible data-only set
i2 | (Data-Locations ) is Relation-like the U1 of SCMPDS -defined Data-Locations -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible set
j1 . (DataLoc (i6,i5)) is V11() V12() ext-real integer set
j1 . (intpos (WB1 + 1)) is V11() V12() ext-real integer set
j1 . (intpos WB1) is V11() V12() ext-real integer set
j1 . i4 is V11() V12() ext-real integer set
j2 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(GBP,5) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,5,GBP,2) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,3) := (GBP,2) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (GBP,3,1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
8 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
<*GBP,3,1*> is set
K75(8,0,<*GBP,3,1*>) is set
((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(GBP,7) := (GBP,5) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
AddTo (GBP,5,(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,5,(- 1)*> is set
K75(8,0,<*GBP,5,(- 1)*>) is set
((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
intpos 4 is Int-like Element of the U1 of SCMPDS
K397(4) is Int-like Element of the U1 of K388()
6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(GBP,6) := ((intpos 4),0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
intpos 2 is Int-like Element of the U1 of SCMPDS
K397(2) is Int-like Element of the U1 of K388()
SubFrom (GBP,6,(intpos 2),0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (GBP,4,(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,4,(- 1)*> is set
K75(8,0,<*GBP,4,(- 1)*>) is set
AddTo (GBP,7,(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,7,(- 1)*> is set
K75(8,0,<*GBP,7,(- 1)*>) is set
(AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,5) := 0 is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,5,0*> is set
K75(7,0,<*GBP,5,0*>) is set
Load ((GBP,5) := 0) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,((GBP,5) := 0)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
{0} is V1() functional set
K376({0},((GBP,5) := 0)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {((GBP,5) := 0)} -valued Function-like constant V23({0}) V27({0},{((GBP,5) := 0)}) Element of K6(K7({0},{((GBP,5) := 0)}))
{((GBP,5) := 0)} is V1() set
K7({0},{((GBP,5) := 0)}) is Relation-like set
K6(K7({0},{((GBP,5) := 0)})) is set
if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
(((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
(GBP,5) := (GBP,7) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,6) := ((intpos 2),0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
intpos 3 is Int-like Element of the U1 of SCMPDS
K397(3) is Int-like Element of the U1 of K388()
SubFrom (GBP,6,(intpos 3),0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,7) := 0 is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,7,0*> is set
K75(7,0,<*GBP,7,0*>) is set
Load ((GBP,7) := 0) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,((GBP,7) := 0)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},((GBP,7) := 0)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {((GBP,7) := 0)} -valued Function-like constant V23({0}) V27({0},{((GBP,7) := 0)}) Element of K6(K7({0},{((GBP,7) := 0)}))
{((GBP,7) := 0)} is V1() set
K7({0},{((GBP,7) := 0)}) is Relation-like set
K6(K7({0},{((GBP,7) := 0)})) is set
if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
(((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
(while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
((intpos 4),0) := ((intpos 3),0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((intpos 3),0) := (GBP,6) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
- 2 is V11() V12() ext-real non positive integer set
AddTo (GBP,5,(- 2)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,5,(- 2)*> is set
K75(8,0,<*GBP,5,(- 2)*>) is set
((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
(((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
((intpos 4),0) := ((intpos 2),0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
((intpos 2),0) := (GBP,6) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))) ';' (((intpos 2),0) := (GBP,6)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
() is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
GBP := 0 is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,0*> is set
K75(2,0,<*GBP,0*>) is set
SBP := 1 is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,1*> is set
K75(2,0,<*SBP,1*>) is set
(GBP := 0) ';' (SBP := 1) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
i2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i2 + i1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,(i2 + i1)) := (i2 + 1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,(i2 + i1),(i2 + 1)*> is set
K75(7,0,<*SBP,(i2 + i1),(i2 + 1)*>) is set
((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(i2 + i1)) := (i2 + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(i2 + i1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((i2 + i1) + 1)) := (i2 + i1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((i2 + i1) + 1),(i2 + i1)*> is set
K75(7,0,<*SBP,((i2 + i1) + 1),(i2 + i1)*>) is set
(((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(i2 + i1)) := (i2 + 1))) ';' ((SBP,((i2 + i1) + 1)) := (i2 + i1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,((i2 + i1) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,2,SBP,(i2 + i1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,((i2 + i1) + 1))) ';' (SubFrom (GBP,2,SBP,(i2 + i1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,(i2 + i1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(GBP,4) := (SBP,((i2 + i1) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1)))) ';' () is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(i2 + i1) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(SBP,((i2 + i1) + 1)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(i2 + i1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((i2 + i1) + 2)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((i2 + i1) + 1),(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((i2 + i1) + 1),(- 1)*> is set
K75(8,0,<*SBP,((i2 + i1) + 1),(- 1)*>) is set
((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((i2 + i1) + 2),1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((i2 + i1) + 2),1*> is set
K75(8,0,<*SBP,((i2 + i1) + 2),1*>) is set
(((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (GBP,1,2) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,1,2*> is set
K75(8,0,<*GBP,1,2*>) is set
((((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1))) ';' (AddTo (GBP,1,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1)))) ';' ()) ';' (((((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
AddTo (GBP,1,(- 2)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*GBP,1,(- 2)*> is set
K75(8,0,<*GBP,1,(- 2)*>) is set
Load (AddTo (GBP,1,(- 2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() halt-free V98( SCMPDS ) V160() set
K385(0,(AddTo (GBP,1,(- 2)))) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(AddTo (GBP,1,(- 2)))) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(AddTo (GBP,1,(- 2)))} -valued Function-like constant V23({0}) V27({0},{(AddTo (GBP,1,(- 2)))}) Element of K6(K7({0},{(AddTo (GBP,1,(- 2)))}))
{(AddTo (GBP,1,(- 2)))} is V1() set
K7({0},{(AddTo (GBP,1,(- 2)))}) is Relation-like set
K6(K7({0},{(AddTo (GBP,1,(- 2)))})) is set
if>0 (GBP,2,(((((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1)))) ';' ()) ';' (((((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((GBP,2) := (SBP,((i2 + i1) + 1))) ';' (SubFrom (GBP,2,SBP,(i2 + i1)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1)))) ';' ()) ';' (((((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
while>0 (GBP,1,((((GBP,2) := (SBP,((i2 + i1) + 1))) ';' (SubFrom (GBP,2,SBP,(i2 + i1)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1)))) ';' ()) ';' (((((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(i2 + i1)) := (i2 + 1))) ';' ((SBP,((i2 + i1) + 1)) := (i2 + i1))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((i2 + i1) + 1))) ';' (SubFrom (GBP,2,SBP,(i2 + i1)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(i2 + i1))) ';' ((GBP,4) := (SBP,((i2 + i1) + 1)))) ';' ()) ';' (((((((SBP,((i2 + i1) + 3)) := (SBP,((i2 + i1) + 1))) ';' ((SBP,((i2 + i1) + 1)) := (GBP,4))) ';' ((SBP,((i2 + i1) + 2)) := (GBP,4))) ';' (AddTo (SBP,((i2 + i1) + 1),(- 1)))) ';' (AddTo (SBP,((i2 + i1) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
intpos 5 is Int-like Element of the U1 of SCMPDS
K397(5) is Int-like Element of the U1 of K388()
intpos 6 is Int-like Element of the U1 of SCMPDS
K397(6) is Int-like Element of the U1 of K388()
intpos 7 is Int-like Element of the U1 of SCMPDS
K397(7) is Int-like Element of the U1 of K388()
card ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0)))) + (card (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
4 + (card (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (Load ((GBP,5) := 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (Load ((GBP,5) := 0)) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1))))) + (card (Load ((GBP,5) := 0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card ((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1))))) + (card (Load ((GBP,5) := 0)))) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + (((card ((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1))))) + (card (Load ((GBP,5) := 0)))) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + (card (Load ((GBP,5) := 0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + (card (Load ((GBP,5) := 0)))) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + ((2 + (card (Load ((GBP,5) := 0)))) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + ((2 + 1) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . (intpos 2) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
s . GBP is V11() V12() ext-real integer set
IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 5) is V11() V12() ext-real integer set
(s . (intpos 5)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(s . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
s . (intpos p0) is V11() V12() ext-real integer set
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
s . (intpos P) is V11() V12() ext-real integer set
IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec (((GBP,7) := (GBP,5)),s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,7) := (GBP,5)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,7) := (GBP,5))) . s is set
DataLoc ((s . GBP),7) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 7 is V11() V12() ext-real integer set
K155(((s . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 7))] is set
{1,K155(((s . GBP) + 7))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((s . GBP) + 7))},{1}} is V1() V56() V57() set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 7) is Int-like Element of the U1 of SCMPDS
K397((0 + 7)) is Int-like Element of the U1 of K388()
(Exec (((GBP,7) := (GBP,5)),s)) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,7) := (GBP,5)),s)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,7) := (GBP,5)),s)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((Exec (((GBP,7) := (GBP,5)),s)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,7) := (GBP,5)),s)) . GBP) + 5))] is set
{1,K155((((Exec (((GBP,7) := (GBP,5)),s)) . GBP) + 5))} is V1() set
{{1,K155((((Exec (((GBP,7) := (GBP,5)),s)) . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,5,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,5,(- 1)))) . (Exec (((GBP,7) := (GBP,5)),s)) is set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos 4) is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4)) + 0 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4)) + 0))] is set
{1,K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4)) + 0))} is V1() set
{{1,K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 4)) + 0))},{1}} is V1() V56() V57() set
p0 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + 0) is Int-like Element of the U1 of SCMPDS
K397((p0 + 0)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
0 + 6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K397((0 + 6)) is Int-like Element of the U1 of K388()
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos 5) is V11() V12() ext-real integer set
Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,4,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,4,(- 1)))) . (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,6) := ((intpos 4),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,6) := ((intpos 4),0))) . (IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) is set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
DataLoc ((s . GBP),5) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 5 is V11() V12() ext-real integer set
K155(((s . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 5))] is set
{1,K155(((s . GBP) + 5))} is V1() set
{{1,K155(((s . GBP) + 5))},{1}} is V1() V56() V57() set
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos 7) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (SubFrom (GBP,6,(intpos 2),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (SubFrom (GBP,6,(intpos 2),0))) . (IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) is set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 7) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos lb) is V11() V12() ext-real integer set
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos lb) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,7) := (GBP,5)),s)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . GBP is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 5 is V11() V12() ext-real integer set
K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 5))] is set
{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 5))} is V1() set
{{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 5))},{1}} is V1() V56() V57() set
DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 4 is V11() V12() ext-real integer set
K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 4))] is set
{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 4))} is V1() set
{{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 4))},{1}} is V1() V56() V57() set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP),7) is Int-like Element of the U1 of SCMPDS
((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP) + 7 is V11() V12() ext-real integer set
K155((((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP) + 7))] is set
{1,K155((((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP) + 7))} is V1() set
{{1,K155((((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP) + 7))},{1}} is V1() V56() V57() set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 6) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 6) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos p0) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 6) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 6) is V11() V12() ext-real integer set
DataLoc (((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)),0) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0 is V11() V12() ext-real integer set
K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0))] is set
{1,K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0))} is V1() set
{{1,K155((((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0))},{1}} is V1() V56() V57() set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (DataLoc (((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)),0)) is V11() V12() ext-real integer set
((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 6)) - ((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (DataLoc (((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)),0))) is V11() V12() ext-real integer set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (P + 0) is Int-like Element of the U1 of SCMPDS
K397((P + 0)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos (P + 0)) is V11() V12() ext-real integer set
((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 6)) - ((IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos (P + 0))) is V11() V12() ext-real integer set
(s . (intpos p0)) - (s . (intpos P)) is V11() V12() ext-real integer set
DataLoc (((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (DataLoc (((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP),6)) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 1) is V11() V12() ext-real integer set
DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))] is set
{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,5) := 0) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,5) := 0)) . (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 3) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos lb) is V11() V12() ext-real integer set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos lb) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))] is set
{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,7,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,7,(- 1)))) . (Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) is set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos 3) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos lb) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos lb) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos lb) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos lb) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))] is set
{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec (((GBP,7) := (GBP,5)),s)))) . (intpos 5) is V11() V12() ext-real integer set
((Exec (((GBP,7) := (GBP,5)),s)) . (intpos 5)) + (- 1) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 5) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec ((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 2),0)),(IExec (((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
0 + 4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K397((0 + 4)) is Int-like Element of the U1 of K388()
DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))] is set
{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (DataLoc (((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . GBP),6)) is V11() V12() ext-real integer set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (DataLoc (((IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 5) is V11() V12() ext-real integer set
IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 5) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,7,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,7,(- 1)))) . (Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) is set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 5) is V11() V12() ext-real integer set
Initialize (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))))) . (intpos 4) is V11() V12() ext-real integer set
IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 4) is V11() V12() ext-real integer set
((Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) . (intpos 4)) + (- 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))))) . (intpos 7) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 7) is V11() V12() ext-real integer set
((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 7)) + (- 1) is V11() V12() ext-real integer set
((Exec ((AddTo (GBP,4,(- 1))),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,5) := 0) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,5) := 0)) . (Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))) is set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0)))),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,5) := 0)),p0,(Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
(Exec (((GBP,5) := 0),(Initialize (Initialize (IExec ((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))),p0,s)))))) . (intpos 7) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
P + (s . (intpos 5)) is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos p0) is V11() V12() ext-real integer set
1 + 0 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(s . (intpos 5)) - 1 is V11() V12() ext-real integer set
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(pn + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
P + ((pn + 1) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l2 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l2 . GBP is V11() V12() ext-real integer set
l2 . (intpos 5) is V11() V12() ext-real integer set
l2 . (intpos 4) is V11() V12() ext-real integer set
P + (l2 . (intpos 5)) is V11() V12() ext-real integer set
l2 . (intpos 2) is V11() V12() ext-real integer set
l2 . (intpos 1) is V11() V12() ext-real integer set
l2 . (intpos 3) is V11() V12() ext-real integer set
l3 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos p0) is V11() V12() ext-real integer set
DataLoc ((l2 . GBP),5) is Int-like Element of the U1 of SCMPDS
(l2 . GBP) + 5 is V11() V12() ext-real integer set
K155(((l2 . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((l2 . GBP) + 5))] is set
{1,K155(((l2 . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((l2 . GBP) + 5))},{1}} is V1() V56() V57() set
IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 1) is V11() V12() ext-real integer set
intpos (P + ((pn + 1) + 1)) is Int-like Element of the U1 of SCMPDS
K397((P + ((pn + 1) + 1))) is Int-like Element of the U1 of K388()
l2 . (intpos (P + ((pn + 1) + 1))) is V11() V12() ext-real integer set
l2 . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 7) is V11() V12() ext-real integer set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
l8 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l8 . (DataLoc ((l2 . GBP),5)) is V11() V12() ext-real integer set
P + (l8 . (DataLoc ((l2 . GBP),5))) is V11() V12() ext-real integer set
l8 . (intpos 4) is V11() V12() ext-real integer set
l8 . (intpos 2) is V11() V12() ext-real integer set
l8 . GBP is V11() V12() ext-real integer set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
l8 . (intpos l0) is V11() V12() ext-real integer set
l8 . (intpos p0) is V11() V12() ext-real integer set
l9 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (intpos 5) is V11() V12() ext-real integer set
l8 . (intpos 5) is V11() V12() ext-real integer set
(l8 . (intpos 5)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (intpos 4) is V11() V12() ext-real integer set
(l8 . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (intpos 7) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5)) is V11() V12() ext-real integer set
(P + (l8 . (DataLoc ((l2 . GBP),5)))) - 1 is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (DataLoc ((l2 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l9,l8)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 3) is V11() V12() ext-real integer set
(l2 . (intpos 5)) - 1 is V11() V12() ext-real integer set
(l2 . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP) + 5))] is set
{1,K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP) + 5))} is V1() set
{{1,K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP) + 5))},{1}} is V1() V56() V57() set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos 2) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos 5)) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos 5) is V11() V12() ext-real integer set
P + ((Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos 5)) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos 3) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))))) . (intpos p0) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
P + l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (P + l8) is Int-like Element of the U1 of SCMPDS
K397((P + l8)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))))) . (intpos (P + l8)) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l9) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (intpos l9) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos l9) is V11() V12() ext-real integer set
l2 . (intpos l9) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l9) is V11() V12() ext-real integer set
l2 . (intpos l9) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos (P + l8)) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos (P + ((pn + 1) + 1))) is V11() V12() ext-real integer set
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l9) is V11() V12() ext-real integer set
l9 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l9) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . (DataLoc (((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP),5)) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (DataLoc (((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . GBP),5)) is V11() V12() ext-real integer set
l8 is Int-like Element of the U1 of SCMPDS
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . l8 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))))) . l8 is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2))) . l8 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . l8 is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l8) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l3,l2)) . (intpos l8) is V11() V12() ext-real integer set
l2 . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l8) is V11() V12() ext-real integer set
l2 . (intpos l8) is V11() V12() ext-real integer set
l8 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
P + l8 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (P + l8) is Int-like Element of the U1 of SCMPDS
K397((P + l8)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos (P + l8)) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos l9) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l3,l2)) . (intpos (P + ((pn + 1) + 1))) is V11() V12() ext-real integer set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
P + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l1 . GBP is V11() V12() ext-real integer set
l1 . (intpos 5) is V11() V12() ext-real integer set
l1 . (intpos 4) is V11() V12() ext-real integer set
P + (l1 . (intpos 5)) is V11() V12() ext-real integer set
l1 . (intpos 2) is V11() V12() ext-real integer set
l1 . (intpos 1) is V11() V12() ext-real integer set
l1 . (intpos 3) is V11() V12() ext-real integer set
l2 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
DataLoc ((l1 . GBP),5) is Int-like Element of the U1 of SCMPDS
(l1 . GBP) + 5 is V11() V12() ext-real integer set
K155(((l1 . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((l1 . GBP) + 5))] is set
{1,K155(((l1 . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((l1 . GBP) + 5))},{1}} is V1() V56() V57() set
intpos (P + 1) is Int-like Element of the U1 of SCMPDS
K397((P + 1)) is Int-like Element of the U1 of K388()
l1 . (intpos (P + 1)) is V11() V12() ext-real integer set
l1 . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos 5) is V11() V12() ext-real integer set
(l1 . (intpos 5)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos 4) is V11() V12() ext-real integer set
(l1 . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos 7) is V11() V12() ext-real integer set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
l6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l6 . (DataLoc ((l1 . GBP),5)) is V11() V12() ext-real integer set
P + (l6 . (DataLoc ((l1 . GBP),5))) is V11() V12() ext-real integer set
l6 . (intpos 4) is V11() V12() ext-real integer set
l6 . (intpos 2) is V11() V12() ext-real integer set
l6 . GBP is V11() V12() ext-real integer set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
l6 . (intpos l8) is V11() V12() ext-real integer set
l6 . (intpos p0) is V11() V12() ext-real integer set
l7 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (intpos 5) is V11() V12() ext-real integer set
l6 . (intpos 5) is V11() V12() ext-real integer set
(l6 . (intpos 5)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (intpos 4) is V11() V12() ext-real integer set
(l6 . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (intpos 7) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5)) is V11() V12() ext-real integer set
(P + (l6 . (DataLoc ((l1 . GBP),5)))) - 1 is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (DataLoc ((l1 . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l7,l6)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP) + 5))] is set
{1,K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP) + 5))} is V1() set
{{1,K155((((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP) + 5))},{1}} is V1() V56() V57() set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (DataLoc (((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP),5)) is V11() V12() ext-real integer set
Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1))) . (DataLoc (((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . GBP),5)) is V11() V12() ext-real integer set
l6 is Int-like Element of the U1 of SCMPDS
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . l6 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1))))) . l6 is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1))) . l6 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . l6 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos 3) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l6 is Int-like Element of the U1 of SCMPDS
K397(l6) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos l6) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l2,l1)) . (intpos l6) is V11() V12() ext-real integer set
l1 . (intpos l6) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l6 is Int-like Element of the U1 of SCMPDS
K397(l6) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos l6) is V11() V12() ext-real integer set
l1 . (intpos l6) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos (P + 1)) is V11() V12() ext-real integer set
l6 is V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() Element of NAT
P + l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (P + l6) is Int-like Element of the U1 of SCMPDS
K397((P + l6)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos (P + l6)) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l7 is Int-like Element of the U1 of SCMPDS
K397(l7) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos l7) is V11() V12() ext-real integer set
l6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
P + l6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (P + l6) is Int-like Element of the U1 of SCMPDS
K397((P + l6)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos (P + l6)) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l7 is Int-like Element of the U1 of SCMPDS
K397(l7) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),l2,l1)) . (intpos l7) is V11() V12() ext-real integer set
pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos pn is Int-like Element of the U1 of SCMPDS
K397(pn) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos pn) is V11() V12() ext-real integer set
s . (intpos pn) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
P + (s . (intpos 5)) is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
DataLoc ((s . GBP),5) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 5 is V11() V12() ext-real integer set
K155(((s . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 5))] is set
{1,K155(((s . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((s . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
pn is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
pn . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
P + (pn . (DataLoc ((s . GBP),5))) is V11() V12() ext-real integer set
pn . (intpos 4) is V11() V12() ext-real integer set
pn . (intpos 2) is V11() V12() ext-real integer set
pn . GBP is V11() V12() ext-real integer set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l2 is Int-like Element of the U1 of SCMPDS
K397(l2) is Int-like Element of the U1 of K388()
pn . (intpos l2) is V11() V12() ext-real integer set
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
pn . (intpos p0) is V11() V12() ext-real integer set
l1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
pn . (intpos 5) is V11() V12() ext-real integer set
(pn . (intpos 5)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (intpos 4) is V11() V12() ext-real integer set
(pn . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (intpos 7) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
(P + (pn . (DataLoc ((s . GBP),5)))) - 1 is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
P + ((IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (DataLoc ((s . GBP),5))) is V11() V12() ext-real integer set
(IExec (((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))),l1,pn)) . (intpos 2) is V11() V12() ext-real integer set
card (while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
11 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
9 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0)))) + (card (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
4 + (card (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (Load ((GBP,7) := 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (Load ((GBP,7) := 0)) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1))))) + (card (Load ((GBP,7) := 0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card ((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1))))) + (card (Load ((GBP,7) := 0)))) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + (((card ((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1))))) + (card (Load ((GBP,7) := 0)))) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + (card (Load ((GBP,7) := 0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + (card (Load ((GBP,7) := 0)))) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + ((2 + (card (Load ((GBP,7) := 0)))) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + ((2 + 1) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
9 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . (intpos 2) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
s . GBP is V11() V12() ext-real integer set
IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
s . (intpos 7) is V11() V12() ext-real integer set
(s . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
s . (intpos P) is V11() V12() ext-real integer set
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
s . (intpos p0) is V11() V12() ext-real integer set
IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec (((GBP,5) := (GBP,7)),s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,5) := (GBP,7)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,5) := (GBP,7))) . s is set
DataLoc ((s . GBP),5) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 5 is V11() V12() ext-real integer set
K155(((s . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 5))] is set
{1,K155(((s . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((s . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,7)),s)) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,5) := (GBP,7)),s)) . GBP),7) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,5) := (GBP,7)),s)) . GBP) + 7 is V11() V12() ext-real integer set
K155((((Exec (((GBP,5) := (GBP,7)),s)) . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,5) := (GBP,7)),s)) . GBP) + 7))] is set
{1,K155((((Exec (((GBP,5) := (GBP,7)),s)) . GBP) + 7))} is V1() set
{{1,K155((((Exec (((GBP,5) := (GBP,7)),s)) . GBP) + 7))},{1}} is V1() V56() V57() set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 7) is Int-like Element of the U1 of SCMPDS
K397((0 + 7)) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,7,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,7,(- 1)))) . (Exec (((GBP,5) := (GBP,7)),s)) is set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2)),0) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2)) + 0 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2)) + 0))] is set
{1,K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2)) + 0))} is V1() set
{{1,K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 2)) + 0))},{1}} is V1() V56() V57() set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (P + 0) is Int-like Element of the U1 of SCMPDS
K397((P + 0)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
0 + 6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K397((0 + 6)) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos 7) is V11() V12() ext-real integer set
Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,3,1)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,3,1))) . (Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) is set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,6) := ((intpos 2),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,6) := ((intpos 2),0))) . (IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) is set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 3) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (SubFrom (GBP,6,(intpos 3),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (SubFrom (GBP,6,(intpos 3),0))) . (IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) is set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),7) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 7 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 7))] is set
{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 7))} is V1() set
{{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 7))},{1}} is V1() V56() V57() set
DataLoc ((s . GBP),7) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 7 is V11() V12() ext-real integer set
K155(((s . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 7))] is set
{1,K155(((s . GBP) + 7))} is V1() set
{{1,K155(((s . GBP) + 7))},{1}} is V1() V56() V57() set
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 5) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),3) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 3 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 3))] is set
{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 3))} is V1() set
{{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 3))},{1}} is V1() V56() V57() set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP) + 5 is V11() V12() ext-real integer set
K155((((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP) + 5))] is set
{1,K155((((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP) + 5))} is V1() set
{{1,K155((((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP) + 5))},{1}} is V1() V56() V57() set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos l8) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,7)),s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos l8) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 6) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 6) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos P) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 6) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 6) is V11() V12() ext-real integer set
DataLoc (((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)),0) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)) + 0 is V11() V12() ext-real integer set
K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)) + 0))] is set
{1,K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)) + 0))} is V1() set
{{1,K155((((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)) + 0))},{1}} is V1() V56() V57() set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (DataLoc (((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)),0)) is V11() V12() ext-real integer set
((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 6)) - ((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (DataLoc (((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 3)),0))) is V11() V12() ext-real integer set
p0 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + 0) is Int-like Element of the U1 of SCMPDS
K397((p0 + 0)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos (p0 + 0)) is V11() V12() ext-real integer set
((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 6)) - ((IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos (p0 + 0))) is V11() V12() ext-real integer set
(s . (intpos P)) - (s . (intpos p0)) is V11() V12() ext-real integer set
DataLoc (((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (DataLoc (((IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . GBP),6)) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))] is set
{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,7) := 0) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,7) := 0)) . (Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) is set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos l8) is V11() V12() ext-real integer set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos l8) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))] is set
{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,5,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,5,(- 1)))) . (Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) is set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos 4) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos l8) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos l8) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))] is set
{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6)) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,7,(- 1))),(Exec (((GBP,5) := (GBP,7)),s)))) . (intpos 7) is V11() V12() ext-real integer set
((Exec (((GBP,5) := (GBP,7)),s)) . (intpos 7)) + (- 1) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 2),0)),(IExec ((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))),p0,s)))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 7) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,6,(intpos 3),0)),(IExec (((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))),p0,s)))) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (intpos 3) is V11() V12() ext-real integer set
0 + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 3) is Int-like Element of the U1 of SCMPDS
K397((0 + 3)) is Int-like Element of the U1 of K388()
DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))] is set
{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))} is V1() set
{{1,K155((((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP) + 6))},{1}} is V1() V56() V57() set
(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . (DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6)) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)) . (DataLoc (((Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) . GBP),6)) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,5,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,5,(- 1)))) . (Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) is set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos 7) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 1))),(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5)) + (- 1) is V11() V12() ext-real integer set
((Exec ((AddTo (GBP,3,1)),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5)) - 1 is V11() V12() ext-real integer set
IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,7) := 0) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,7) := 0)) . (Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))) is set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((Load ((GBP,7) := 0)),p0,(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
(Exec (((GBP,7) := 0),(Initialize (IExec ((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 7) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 3)) + (s . (intpos 7)) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos p0) is V11() V12() ext-real integer set
1 + 0 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(s . (intpos 7)) - 1 is V11() V12() ext-real integer set
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l1 . GBP is V11() V12() ext-real integer set
DataLoc ((l1 . GBP),7) is Int-like Element of the U1 of SCMPDS
(l1 . GBP) + 7 is V11() V12() ext-real integer set
K155(((l1 . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((l1 . GBP) + 7))] is set
{1,K155(((l1 . GBP) + 7))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((l1 . GBP) + 7))},{1}} is V1() V56() V57() set
l1 . (intpos 7) is V11() V12() ext-real integer set
(pn + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l1 . (intpos 3) is V11() V12() ext-real integer set
(l1 . (intpos 3)) + (l1 . (intpos 7)) is V11() V12() ext-real integer set
l1 . (intpos 2) is V11() V12() ext-real integer set
l2 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
l1 . (intpos p0) is V11() V12() ext-real integer set
l4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l4 is Int-like Element of the U1 of SCMPDS
K397(l4) is Int-like Element of the U1 of K388()
l1 . (intpos l4) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 7) is V11() V12() ext-real integer set
(l1 . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 3) is V11() V12() ext-real integer set
(l1 . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 5) is V11() V12() ext-real integer set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 7) is Int-like Element of the U1 of SCMPDS
K397((0 + 7)) is Int-like Element of the U1 of K388()
l7 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l7 . (intpos 3) is V11() V12() ext-real integer set
l7 . (intpos 2) is V11() V12() ext-real integer set
l7 . GBP is V11() V12() ext-real integer set
l7 . (DataLoc ((l1 . GBP),7)) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l8 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . GBP is V11() V12() ext-real integer set
l7 . (intpos p0) is V11() V12() ext-real integer set
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
l7 . (intpos l9) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (intpos 7) is V11() V12() ext-real integer set
l7 . (intpos 7) is V11() V12() ext-real integer set
(l7 . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (intpos 3) is V11() V12() ext-real integer set
(l7 . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (DataLoc ((l1 . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (DataLoc ((l1 . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (DataLoc ((l1 . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (DataLoc ((l1 . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l8,l7)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP),7) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP) + 7 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP) + 7))] is set
{1,K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP) + 7))} is V1() set
{{1,K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP) + 7))},{1}} is V1() V56() V57() set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 1) is V11() V12() ext-real integer set
l1 . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 4) is V11() V12() ext-real integer set
l1 . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 2) is V11() V12() ext-real integer set
Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (intpos 2) is V11() V12() ext-real integer set
((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 3)) + ((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos 7)) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (intpos 7) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))))) . (intpos p0) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l8 + l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))))) . (intpos l8) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 4) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (intpos l9) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos l9) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l9) is V11() V12() ext-real integer set
l1 . (intpos l9) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l9) is V11() V12() ext-real integer set
l1 . (intpos l9) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 3) is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l0 + l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos lb) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l0) is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . (DataLoc (((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (DataLoc (((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . GBP),7)) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
l7 is Int-like Element of the U1 of SCMPDS
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . l7 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))))) . l7 is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1))) . l7 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . l7 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 4) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l7 is Int-like Element of the U1 of SCMPDS
K397(l7) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l7) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l2,l1)) . (intpos l7) is V11() V12() ext-real integer set
l1 . (intpos l7) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l7 is Int-like Element of the U1 of SCMPDS
K397(l7) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l7) is V11() V12() ext-real integer set
l1 . (intpos l7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 5) is V11() V12() ext-real integer set
l7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 3) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l8 + l7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l9) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l4) is V11() V12() ext-real integer set
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l8) is V11() V12() ext-real integer set
l1 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l1 . GBP is V11() V12() ext-real integer set
l1 . (intpos 7) is V11() V12() ext-real integer set
l1 . (intpos 3) is V11() V12() ext-real integer set
(l1 . (intpos 3)) + (l1 . (intpos 7)) is V11() V12() ext-real integer set
l1 . (intpos 2) is V11() V12() ext-real integer set
l2 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 1) is V11() V12() ext-real integer set
l1 . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 4) is V11() V12() ext-real integer set
l1 . (intpos 4) is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l3 is Int-like Element of the U1 of SCMPDS
K397(l3) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos l3) is V11() V12() ext-real integer set
l1 . (intpos l3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l2,l1)) . (intpos p0) is V11() V12() ext-real integer set
pn is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
pn . GBP is V11() V12() ext-real integer set
DataLoc ((pn . GBP),7) is Int-like Element of the U1 of SCMPDS
(pn . GBP) + 7 is V11() V12() ext-real integer set
K155(((pn . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((pn . GBP) + 7))] is set
{1,K155(((pn . GBP) + 7))} is V1() set
{{1,K155(((pn . GBP) + 7))},{1}} is V1() V56() V57() set
pn . (intpos 7) is V11() V12() ext-real integer set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
pn . (intpos 3) is V11() V12() ext-real integer set
(pn . (intpos 3)) + (pn . (intpos 7)) is V11() V12() ext-real integer set
pn . (intpos 2) is V11() V12() ext-real integer set
l1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
pn . (intpos p0) is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l3 is Int-like Element of the U1 of SCMPDS
K397(l3) is Int-like Element of the U1 of K388()
pn . (intpos l3) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos 7) is V11() V12() ext-real integer set
(pn . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
(pn . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
l6 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l6 . (intpos 3) is V11() V12() ext-real integer set
l6 . (intpos 2) is V11() V12() ext-real integer set
l6 . GBP is V11() V12() ext-real integer set
l6 . (DataLoc ((pn . GBP),7)) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
l6 . (intpos l8) is V11() V12() ext-real integer set
l7 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . GBP is V11() V12() ext-real integer set
l6 . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (intpos 7) is V11() V12() ext-real integer set
l6 . (intpos 7) is V11() V12() ext-real integer set
(l6 . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (intpos 3) is V11() V12() ext-real integer set
(l6 . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (DataLoc ((pn . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (DataLoc ((pn . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (DataLoc ((pn . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (DataLoc ((pn . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l7,l6)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP),7) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP) + 7 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP) + 7))] is set
{1,K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP) + 7))} is V1() set
{{1,K155((((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP) + 7))},{1}} is V1() V56() V57() set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (DataLoc (((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP),7)) is V11() V12() ext-real integer set
Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn))) . (DataLoc (((IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . GBP),7)) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
l6 is Int-like Element of the U1 of SCMPDS
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . l6 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn))))) . l6 is V11() V12() ext-real integer set
(Initialize (IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn))) . l6 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . l6 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos 1) is V11() V12() ext-real integer set
pn . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 7) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos 4) is V11() V12() ext-real integer set
pn . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 4) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l6 is Int-like Element of the U1 of SCMPDS
K397(l6) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l6) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),l1,pn)) . (intpos l6) is V11() V12() ext-real integer set
pn . (intpos l6) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l6 is Int-like Element of the U1 of SCMPDS
K397(l6) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l6) is V11() V12() ext-real integer set
pn . (intpos l6) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
l6 is V1() epsilon-transitive epsilon-connected ordinal T-Sequence-like c=-linear natural V11() V12() Relation-like non-empty empty-yielding RAT -valued Function-like one-to-one constant functional ext-real non positive non negative V33() V34() V35() V36() integer V88() V111() V112() V159() Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l7 + l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos p0) is V11() V12() ext-real integer set
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l8) is V11() V12() ext-real integer set
intpos l7 is Int-like Element of the U1 of SCMPDS
K397(l7) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
l6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l7 + l6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos p0) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l8) is V11() V12() ext-real integer set
intpos l7 is Int-like Element of the U1 of SCMPDS
K397(l7) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos p0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos p0) is V11() V12() ext-real integer set
pn is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
pn . GBP is V11() V12() ext-real integer set
pn . (intpos 7) is V11() V12() ext-real integer set
pn . (intpos 3) is V11() V12() ext-real integer set
(pn . (intpos 3)) + (pn . (intpos 7)) is V11() V12() ext-real integer set
pn . (intpos 2) is V11() V12() ext-real integer set
l1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 1) is V11() V12() ext-real integer set
pn . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 4) is V11() V12() ext-real integer set
pn . (intpos 4) is V11() V12() ext-real integer set
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l2 is Int-like Element of the U1 of SCMPDS
K397(l2) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos l2) is V11() V12() ext-real integer set
pn . (intpos l2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),l1,pn)) . (intpos p0) is V11() V12() ext-real integer set
pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos pn is Int-like Element of the U1 of SCMPDS
K397(pn) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,s)) . (intpos pn) is V11() V12() ext-real integer set
s . (intpos pn) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
DataLoc ((s . GBP),7) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 7 is V11() V12() ext-real integer set
K155(((s . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 7))] is set
{1,K155(((s . GBP) + 7))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((s . GBP) + 7))},{1}} is V1() V56() V57() set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 7) is Int-like Element of the U1 of SCMPDS
K397((0 + 7)) is Int-like Element of the U1 of K388()
n is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
n . (intpos 3) is V11() V12() ext-real integer set
n . (intpos 2) is V11() V12() ext-real integer set
n . GBP is V11() V12() ext-real integer set
n . (DataLoc ((s . GBP),7)) is V11() V12() ext-real integer set
l1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . GBP is V11() V12() ext-real integer set
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
n . (intpos P) is V11() V12() ext-real integer set
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (intpos 7) is V11() V12() ext-real integer set
n . (intpos 7) is V11() V12() ext-real integer set
(n . (intpos 7)) - 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (intpos 3) is V11() V12() ext-real integer set
(n . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (DataLoc ((s . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (DataLoc ((s . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (DataLoc ((s . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (DataLoc ((s . GBP),7)) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))),pn,n)) . (intpos 2) is V11() V12() ext-real integer set
card (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
29 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))))) + (card (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
11 + 11 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(11 + 11) + (card (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 + ((card (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1)))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1)))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 + (((card ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1)))) + 1) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2))))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((card (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2))))) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 + ((((card (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2))))) + 1) + 1) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6)))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6)))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((card ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6)))) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((((card ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6)))) + 1) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 + (((((card ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6)))) + 1) + 1) + 1) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)))) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((((card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)))) + 1) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((((card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)))) + 1) + 1) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 + ((((((card (((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0)))) + 1) + 1) + 1) + 1) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((2 + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((2 + 1) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((((2 + 1) + 1) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
22 + (((((2 + 1) + 1) + 1) + 1) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
31 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
29 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card () is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom () is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
38 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0)))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0)))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0)))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((card ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1)))) + (card (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1)))) + (card (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((card (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1)))) + (card (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((((card (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1)))) + (card (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + 31 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(4 + 31) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((4 + 31) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((4 + 31) + 1) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
s +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 3)) + 1 is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(s . (intpos 4)) - 1 is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(s . (intpos 5)) - 2 is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos P) is V11() V12() ext-real integer set
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
s . (intpos p0) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
s . (intpos P) is V11() V12() ext-real integer set
IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec (((GBP,6) := ((intpos 4),0)),(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,6) := ((intpos 4),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,6) := ((intpos 4),0))) . (Initialize s) is set
(Initialize s) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize s) . GBP),6) is Int-like Element of the U1 of SCMPDS
((Initialize s) . GBP) + 6 is V11() V12() ext-real integer set
K155((((Initialize s) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize s) . GBP) + 6))] is set
{1,K155((((Initialize s) . GBP) + 6))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((((Initialize s) . GBP) + 6))},{1}} is V1() V56() V57() set
0 + 6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K397((0 + 6)) is Int-like Element of the U1 of K388()
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . GBP is V11() V12() ext-real integer set
(Initialize s) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4)) + 0 is V11() V12() ext-real integer set
K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4)) + 0))] is set
{1,K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4)) + 0))} is V1() set
{{1,K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 4)) + 0))},{1}} is V1() V56() V57() set
p0 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + 0) is Int-like Element of the U1 of SCMPDS
K397((p0 + 0)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (((intpos 4),0) := ((intpos 3),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (((intpos 4),0) := ((intpos 3),0))) . (Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) is set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . GBP is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 6) is V11() V12() ext-real integer set
DataLoc (((Initialize s) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
((Initialize s) . (intpos 4)) + 0 is V11() V12() ext-real integer set
K155((((Initialize s) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize s) . (intpos 4)) + 0))] is set
{1,K155((((Initialize s) . (intpos 4)) + 0))} is V1() set
{{1,K155((((Initialize s) . (intpos 4)) + 0))},{1}} is V1() V56() V57() set
(Initialize s) . (DataLoc (((Initialize s) . (intpos 4)),0)) is V11() V12() ext-real integer set
(Initialize s) . (intpos (p0 + 0)) is V11() V12() ext-real integer set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 6) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos 6) is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP) + 6))] is set
{1,K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP) + 6))} is V1() set
{{1,K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP) + 6))},{1}} is V1() V56() V57() set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (DataLoc (((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . GBP),6)) is V11() V12() ext-real integer set
(Initialize s) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3)),0) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3)) + 0 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3)) + 0))] is set
{1,K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3)) + 0))} is V1() set
{{1,K155((((IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 3)) + 0))},{1}} is V1() V56() V57() set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (P + 0) is Int-like Element of the U1 of SCMPDS
K397((P + 0)) is Int-like Element of the U1 of K388()
(Initialize s) . (intpos P) is V11() V12() ext-real integer set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos p0) is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)),0) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)) + 0 is V11() V12() ext-real integer set
K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)) + 0))] is set
{1,K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)) + 0))} is V1() set
{{1,K155((((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)) + 0))},{1}} is V1() V56() V57() set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (DataLoc (((Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 3)),0)) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos (P + 0)) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (((intpos 3),0) := (GBP,6)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (((intpos 3),0) := (GBP,6))) . (IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) is set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (((intpos 3),0) := (GBP,6)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (((intpos 3),0) := (GBP,6))) . (IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) is set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
(Initialize s) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (((intpos 3),0) := (GBP,6)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (((intpos 3),0) := (GBP,6))) . (IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) is set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP) + 5))] is set
{1,K155((((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP) + 5))} is V1() set
{{1,K155((((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,5,(- 2))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,5,(- 2)))) . (IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) is set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP),3) is Int-like Element of the U1 of SCMPDS
((IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP) + 3 is V11() V12() ext-real integer set
K155((((IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP) + 3))] is set
{1,K155((((IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP) + 3))} is V1() set
{{1,K155((((IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . GBP) + 3))},{1}} is V1() V56() V57() set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
0 + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 3) is Int-like Element of the U1 of SCMPDS
K397((0 + 3)) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,3,1)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,3,1))) . (IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) is set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
P + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos P) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos P) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos P) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos P) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos P) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos P) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos p0) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc ((s . GBP),5) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 5 is V11() V12() ext-real integer set
K155(((s . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 5))] is set
{1,K155(((s . GBP) + 5))} is V1() set
{{1,K155(((s . GBP) + 5))},{1}} is V1() V56() V57() set
(Initialize s) . (intpos 5) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
((IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos 5)) + (- 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
(Initialize s) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP) + 4 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP) + 4))] is set
{1,K155((((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP) + 4))} is V1() set
{{1,K155((((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP) + 4))},{1}} is V1() V56() V57() set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,4,(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,4,(- 1)))) . (IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) is set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . GBP is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos P) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos P) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos p0) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos p0) is V11() V12() ext-real integer set
0 + 4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K397((0 + 4)) is Int-like Element of the U1 of K388()
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
((IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 4)) + (- 1) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(Initialize s) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 3),0)),(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))))) . (intpos l8) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((((intpos 3),0) := (GBP,6)),(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,5,(- 2))),(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))))) . (intpos l8) is V11() V12() ext-real integer set
(IExec (((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,4,(- 1))),(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))) . (intpos l8) is V11() V12() ext-real integer set
(IExec (((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
(IExec ((((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))),p0,(Initialize s))) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 3)) - 1 is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . GBP is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 3)) - 1) + ((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 5)) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 4)) + 1 is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + (s . (intpos 5)) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos P) is V11() V12() ext-real integer set
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
s +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP is V11() V12() ext-real integer set
Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 7) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos 7) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos P) is V11() V12() ext-real integer set
pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + pn) is Int-like Element of the U1 of SCMPDS
K397((p0 + pn)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos (p0 + pn)) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
p0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(p0 + 1) + pn is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP is V11() V12() ext-real integer set
Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . GBP is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos 3) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos 5) is V11() V12() ext-real integer set
((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 3)) + ((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 7)) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
DataLoc (((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP),7) is Int-like Element of the U1 of SCMPDS
((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP) + 7 is V11() V12() ext-real integer set
K155((((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP) + 7)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP) + 7))] is set
{1,K155((((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP) + 7))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP) + 7))},{1}} is V1() V56() V57() set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (DataLoc (((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP),7)) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (DataLoc (((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . GBP),7)) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos 5) is V11() V12() ext-real integer set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 7) is Int-like Element of the U1 of SCMPDS
K397((0 + 7)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5))] is set
{1,K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5))} is V1() set
{{1,K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l8 is Int-like Element of the U1 of SCMPDS
K397(l8) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l8) is V11() V12() ext-real integer set
s . (intpos l8) is V11() V12() ext-real integer set
(p0 + pn) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l9 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l9) is V11() V12() ext-real integer set
s . (intpos l9) is V11() V12() ext-real integer set
l0 is Int-like Element of the U1 of SCMPDS
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . l0 is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . l0 is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . l0 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . l0 is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos l0) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos l0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
s . (intpos l0) is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
s . (intpos l0) is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos P) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos P) is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos l0) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos l0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos P) is V11() V12() ext-real integer set
l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l9 + l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos l9) is V11() V12() ext-real integer set
l9 + ((IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos 7)) is V11() V12() ext-real integer set
stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((p0 +* (stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))))),(Initialize (Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)))),l0) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((p0 +* (stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))))),(Initialize (Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)))),l0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((p0 +* (stop (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))))),(Initialize (Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)))),l0)) . (IC ) is set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . GBP is V11() V12() ext-real integer set
p0 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize (Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 3)) + 1 is V11() V12() ext-real integer set
l9 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 4)) - 1 is V11() V12() ext-real integer set
(p0 + pn) - 1 is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos 5)) - 2 is V11() V12() ext-real integer set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
1 - 2 is V11() V12() ext-real integer set
(- 1) + 1 is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 5)) + 1 is V11() V12() ext-real integer set
(s . (intpos 5)) - 0 is V11() V12() ext-real integer set
l8 - 2 is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l0 + (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos 5)) + 1) is V11() V12() ext-real integer set
l0 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + pn) + (- 1) is V11() V12() ext-real integer set
((p0 + pn) + (- 1)) + 1 is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos L5) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos (p0 + pn)) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos (p0 + pn)) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos l9) is V11() V12() ext-real integer set
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
s . (intpos P) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos l9) is V11() V12() ext-real integer set
(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))) . (intpos l9) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos (p0 + pn)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
s . (intpos l0) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos P) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos l0) is V11() V12() ext-real integer set
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos l0) is V11() V12() ext-real integer set
DataLoc (((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5))] is set
{1,K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((((IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . (intpos 5) is V11() V12() ext-real integer set
(p0 + pn) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((p0 + pn) + 1) - 1 is V11() V12() ext-real integer set
l9 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(l9 + 0) - 1 is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
lb is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
L5 is Int-like Element of the U1 of SCMPDS
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . L5 is V11() V12() ext-real integer set
(IExec ((if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))),p0,(Initialize (IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s))))) . L5 is V11() V12() ext-real integer set
(IExec (((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))),p0,s)) . L5 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . L5 is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
s . (intpos L5) is V11() V12() ext-real integer set
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos l0) is V11() V12() ext-real integer set
s . (intpos l0) is V11() V12() ext-real integer set
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos lb) is V11() V12() ext-real integer set
s . (intpos lb) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos P) is V11() V12() ext-real integer set
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0))))))),p0,(Initialize (IExec ((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
p0 is V11() V12() ext-real integer set
(- 1) + 1 is V11() V12() ext-real integer set
p0 is V11() V12() ext-real integer set
n is V11() V12() ext-real integer set
n + 1 is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + p0 is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is V11() V12() ext-real integer set
n is V11() V12() ext-real integer set
n + 1 is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + p0 is V11() V12() ext-real integer set
s + (- 1) is V11() V12() ext-real integer set
(s + (- 1)) + 1 is V11() V12() ext-real integer set
p0 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
n is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
n . (intpos P) is V11() V12() ext-real integer set
p0 . (intpos P) is V11() V12() ext-real integer set
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
n . (intpos p0) is V11() V12() ext-real integer set
p0 . (intpos p0) is V11() V12() ext-real integer set
s + n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
l1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
len l1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom l1 is V139() Element of K6(NAT)
Seg n is Element of K6(NAT)
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
s + l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l1 . l2 is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (s + l3) is Int-like Element of the U1 of SCMPDS
K397((s + l3)) is Int-like Element of the U1 of K388()
n . (intpos (s + l3)) is V11() V12() ext-real integer set
p0 . (intpos (s + l3)) is V11() V12() ext-real integer set
pn . l2 is V11() V12() ext-real integer set
l1 . l2 is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (s + l3) is Int-like Element of the U1 of SCMPDS
K397((s + l3)) is Int-like Element of the U1 of K388()
p0 . (intpos (s + l3)) is V11() V12() ext-real integer set
pn . l2 is V11() V12() ext-real integer set
l1 . l2 is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (s + l3) is Int-like Element of the U1 of SCMPDS
K397((s + l3)) is Int-like Element of the U1 of K388()
p0 . (intpos (s + l3)) is V11() V12() ext-real integer set
pn . l2 is V11() V12() ext-real integer set
l1 . l2 is V11() V12() ext-real integer set
pn . l2 is V11() V12() ext-real integer set
l1 . l2 is V11() V12() ext-real integer set
pn . l2 is V11() V12() ext-real integer set
P - s is V11() V12() ext-real integer set
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 - s is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l3 + s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l2 + s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn . l2 is V11() V12() ext-real integer set
l1 . l3 is V11() V12() ext-real integer set
l4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l4 + s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + l4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn . l4 is V11() V12() ext-real integer set
intpos (l4 + s) is Int-like Element of the U1 of SCMPDS
K397((l4 + s)) is Int-like Element of the U1 of K388()
p0 . (intpos (l4 + s)) is V11() V12() ext-real integer set
n . (intpos (l4 + s)) is V11() V12() ext-real integer set
l1 . l4 is V11() V12() ext-real integer set
pn . l3 is V11() V12() ext-real integer set
l1 . l2 is V11() V12() ext-real integer set
n is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
p0 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
n . (intpos P) is V11() V12() ext-real integer set
p0 . (intpos P) is V11() V12() ext-real integer set
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
n . (intpos p0) is V11() V12() ext-real integer set
p0 . (intpos p0) is V11() V12() ext-real integer set
n is V11() V12() ext-real integer set
pn is V11() V12() ext-real integer set
l1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
l1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
intpos l1 is Int-like Element of the U1 of SCMPDS
K397(l1) is Int-like Element of the U1 of K388()
n . (intpos l1) is V11() V12() ext-real integer set
p0 . (intpos l1) is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
P is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
P . GBP is V11() V12() ext-real integer set
P . (intpos 5) is V11() V12() ext-real integer set
P . (intpos 4) is V11() V12() ext-real integer set
P . (intpos 3) is V11() V12() ext-real integer set
(P . (intpos 3)) - 1 is V11() V12() ext-real integer set
P . (intpos 2) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos 1) is V11() V12() ext-real integer set
P . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos 4) is V11() V12() ext-real integer set
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n + (P . (intpos 5)) is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
pn + p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos p0 is Int-like Element of the U1 of SCMPDS
K397(p0) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos p0) is V11() V12() ext-real integer set
l1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
l2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len l1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
len l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l3 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l4 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l4 . GBP is V11() V12() ext-real integer set
l4 . (intpos 5) is V11() V12() ext-real integer set
(l3 + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l4 . (intpos 4) is V11() V12() ext-real integer set
l5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l5 + (l4 . (intpos 5)) is V11() V12() ext-real integer set
l4 . (intpos 3) is V11() V12() ext-real integer set
(l4 . (intpos 3)) - 1 is V11() V12() ext-real integer set
l4 . (intpos 2) is V11() V12() ext-real integer set
l8 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP is V11() V12() ext-real integer set
Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . GBP is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 5) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos 5) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 3)) - 1) + ((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 5)) is V11() V12() ext-real integer set
DataLoc ((l4 . GBP),5) is Int-like Element of the U1 of SCMPDS
(l4 . GBP) + 5 is V11() V12() ext-real integer set
K155(((l4 . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((l4 . GBP) + 5))] is set
{1,K155(((l4 . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((l4 . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
lb is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
lb . (intpos 4) is V11() V12() ext-real integer set
lb . (intpos 3) is V11() V12() ext-real integer set
(lb . (intpos 3)) - 1 is V11() V12() ext-real integer set
lb . (intpos 5) is V11() V12() ext-real integer set
((lb . (intpos 3)) - 1) + (lb . (intpos 5)) is V11() V12() ext-real integer set
lb . (intpos 2) is V11() V12() ext-real integer set
lb . GBP is V11() V12() ext-real integer set
lb . (DataLoc ((l4 . GBP),5)) is V11() V12() ext-real integer set
L5 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
TR is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
TR + (lb . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . GBP is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (DataLoc ((l4 . GBP),5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 3) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 5) is V11() V12() ext-real integer set
(((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 3)) - 1) + ((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),L5,lb)) . (intpos 2) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 5)) + 1 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
l6 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
l7 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
DataLoc (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP) + 5))] is set
{1,K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP) + 5))} is V1() set
{{1,K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP) + 5))},{1}} is V1() V56() V57() set
len l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
len l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l4 . (intpos 1) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos 4)) + 1 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos p0) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
TR is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos L5) is V11() V12() ext-real integer set
l4 . (intpos L5) is V11() V12() ext-real integer set
intpos TR is Int-like Element of the U1 of SCMPDS
K397(TR) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos TR) is V11() V12() ext-real integer set
l4 . (intpos TR) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
WB4 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len WB4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WB4 . WH4 is V11() V12() ext-real integer set
pn + WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (pn + WH4) is Int-like Element of the U1 of SCMPDS
K397((pn + WH4)) is Int-like Element of the U1 of K388()
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos (pn + WH4)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos (pn + WH4)) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos WH4) is V11() V12() ext-real integer set
l4 . (intpos WH4) is V11() V12() ext-real integer set
WH4 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH4 . m1 is V11() V12() ext-real integer set
pn + m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (pn + m1) is Int-like Element of the U1 of SCMPDS
K397((pn + m1)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))))) . (intpos (pn + m1)) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos p0) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos p0) is V11() V12() ext-real integer set
dom WH4 is V139() Element of K6(NAT)
Seg p0 is Element of K6(NAT)
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
WH4 . m1 is V11() V12() ext-real integer set
m2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn + m2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (pn + m2) is Int-like Element of the U1 of SCMPDS
K397((pn + m2)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos (pn + m2)) is V11() V12() ext-real integer set
l7 . m1 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))))) . (intpos 4) is V11() V12() ext-real integer set
L5 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos m1 is Int-like Element of the U1 of SCMPDS
K397(m1) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos m1 is Int-like Element of the U1 of SCMPDS
K397(m1) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos m1) is V11() V12() ext-real integer set
L5 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos m1 is Int-like Element of the U1 of SCMPDS
K397(m1) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (intpos m1) is V11() V12() ext-real integer set
l4 . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos m1) is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . (DataLoc (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP),5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (DataLoc (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . GBP),5)) is V11() V12() ext-real integer set
IF4 is Int-like Element of the U1 of SCMPDS
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . IF4 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))))) . IF4 is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4))) . IF4 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . IF4 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 4) is V11() V12() ext-real integer set
IF4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos IF4 is Int-like Element of the U1 of SCMPDS
K397(IF4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
l4 . (intpos IF4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos TR) is V11() V12() ext-real integer set
TR - 1 is V11() V12() ext-real integer set
IF4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos IF4 is Int-like Element of the U1 of SCMPDS
K397(IF4) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos p0) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
IF4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos 4)) + 1 is V11() V12() ext-real integer set
intpos IF4 is Int-like Element of the U1 of SCMPDS
K397(IF4) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
IF4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos IF4 is Int-like Element of the U1 of SCMPDS
K397(IF4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l8,l4)) . (intpos IF4) is V11() V12() ext-real integer set
l4 . (intpos IF4) is V11() V12() ext-real integer set
l4 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l4 . GBP is V11() V12() ext-real integer set
l4 . (intpos 5) is V11() V12() ext-real integer set
l4 . (intpos 4) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l6 + (l4 . (intpos 5)) is V11() V12() ext-real integer set
l4 . (intpos 3) is V11() V12() ext-real integer set
(l4 . (intpos 3)) - 1 is V11() V12() ext-real integer set
l4 . (intpos 2) is V11() V12() ext-real integer set
l7 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
l8 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
l5 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
len l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
len l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 1) is V11() V12() ext-real integer set
l4 . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 4) is V11() V12() ext-real integer set
l9 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l9 is Int-like Element of the U1 of SCMPDS
K397(l9) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos l9) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos p0) is V11() V12() ext-real integer set
l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l0 is Int-like Element of the U1 of SCMPDS
K397(l0) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos l0) is V11() V12() ext-real integer set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos lb is Int-like Element of the U1 of SCMPDS
K397(lb) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos lb) is V11() V12() ext-real integer set
l4 . (intpos lb) is V11() V12() ext-real integer set
1 + 0 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(P . (intpos 5)) - 1 is V11() V12() ext-real integer set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l3 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
l4 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
l4 . GBP is V11() V12() ext-real integer set
l4 . (intpos 5) is V11() V12() ext-real integer set
l4 . (intpos 4) is V11() V12() ext-real integer set
l4 . (intpos 3) is V11() V12() ext-real integer set
(l4 . (intpos 3)) - 1 is V11() V12() ext-real integer set
l4 . (intpos 2) is V11() V12() ext-real integer set
l4 . (intpos 1) is V11() V12() ext-real integer set
l5 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . GBP is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos p0) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l6 + (l4 . (intpos 5)) is V11() V12() ext-real integer set
l7 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
l8 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
len l8 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 3) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 5) is V11() V12() ext-real integer set
(((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 3)) - 1) + ((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 5)) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 4)) + 1 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos p0) is V11() V12() ext-real integer set
TR is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IF4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos TR is Int-like Element of the U1 of SCMPDS
K397(TR) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos TR) is V11() V12() ext-real integer set
l4 . (intpos TR) is V11() V12() ext-real integer set
intpos IF4 is Int-like Element of the U1 of SCMPDS
K397(IF4) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos IF4) is V11() V12() ext-real integer set
l4 . (intpos IF4) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 5)) + 1 is V11() V12() ext-real integer set
DataLoc ((l4 . GBP),5) is Int-like Element of the U1 of SCMPDS
(l4 . GBP) + 5 is V11() V12() ext-real integer set
K155(((l4 . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((l4 . GBP) + 5))] is set
{1,K155(((l4 . GBP) + 5))} is V1() set
{{1,K155(((l4 . GBP) + 5))},{1}} is V1() V56() V57() set
WB4 is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
WB4 . (intpos 4) is V11() V12() ext-real integer set
WB4 . (intpos 3) is V11() V12() ext-real integer set
(WB4 . (intpos 3)) - 1 is V11() V12() ext-real integer set
WB4 . (intpos 5) is V11() V12() ext-real integer set
((WB4 . (intpos 3)) - 1) + (WB4 . (intpos 5)) is V11() V12() ext-real integer set
WB4 . (intpos 2) is V11() V12() ext-real integer set
WB4 . GBP is V11() V12() ext-real integer set
WB4 . (DataLoc ((l4 . GBP),5)) is V11() V12() ext-real integer set
WH4 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
m1 + (WB4 . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . GBP is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (DataLoc ((l4 . GBP),5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 3) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 5) is V11() V12() ext-real integer set
(((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 3)) - 1) + ((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),WH4,WB4)) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP),5) is Int-like Element of the U1 of SCMPDS
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP) + 5 is V11() V12() ext-real integer set
K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP) + 5))] is set
{1,K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP) + 5))} is V1() set
{{1,K155((((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP) + 5))},{1}} is V1() V56() V57() set
Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4))) . (DataLoc (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP),5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (DataLoc (((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . GBP),5)) is V11() V12() ext-real integer set
WB4 is Int-like Element of the U1 of SCMPDS
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . WB4 is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4))))) . WB4 is V11() V12() ext-real integer set
(Initialize (IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4))) . WB4 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . WB4 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos 2) is V11() V12() ext-real integer set
WB4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WB4 is Int-like Element of the U1 of SCMPDS
K397(WB4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
l4 . (intpos WB4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos TR) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos IF4) is V11() V12() ext-real integer set
IF4 - 1 is V11() V12() ext-real integer set
WB4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WB4 is Int-like Element of the U1 of SCMPDS
K397(WB4) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
WB4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos 4)) + 1 is V11() V12() ext-real integer set
intpos WB4 is Int-like Element of the U1 of SCMPDS
K397(WB4) is Int-like Element of the U1 of K388()
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
WB4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WB4 is Int-like Element of the U1 of SCMPDS
K397(WB4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),l5,l4)) . (intpos WB4) is V11() V12() ext-real integer set
l4 . (intpos WB4) is V11() V12() ext-real integer set
l4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l4 is Int-like Element of the U1 of SCMPDS
K397(l4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos l4) is V11() V12() ext-real integer set
l5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l5 is Int-like Element of the U1 of SCMPDS
K397(l5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos l5) is V11() V12() ext-real integer set
l6 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l6 is Int-like Element of the U1 of SCMPDS
K397(l6) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),n,P)) . (intpos l6) is V11() V12() ext-real integer set
P . (intpos l6) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 3)) - 1 is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + (s . (intpos 5)) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
DataLoc ((s . GBP),5) is Int-like Element of the U1 of SCMPDS
(s . GBP) + 5 is V11() V12() ext-real integer set
K155(((s . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155(((s . GBP) + 5))] is set
{1,K155(((s . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155(((s . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
pn is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
pn . (intpos 4) is V11() V12() ext-real integer set
pn . (intpos 3) is V11() V12() ext-real integer set
(pn . (intpos 3)) - 1 is V11() V12() ext-real integer set
pn . (intpos 5) is V11() V12() ext-real integer set
((pn . (intpos 3)) - 1) + (pn . (intpos 5)) is V11() V12() ext-real integer set
pn . (intpos 2) is V11() V12() ext-real integer set
pn . GBP is V11() V12() ext-real integer set
pn . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
l1 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l3 + (pn . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . GBP is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (DataLoc ((s . GBP),5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 3) is V11() V12() ext-real integer set
((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 5) is V11() V12() ext-real integer set
(((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 3)) - 1) + ((IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))),l1,pn)) . (intpos 2) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
s +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 2)) + 1 is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(s . (intpos 4)) - (s . (intpos 2)) is V11() V12() ext-real integer set
IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec (((GBP,5) := (GBP,4)),(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,5) := (GBP,4)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,5) := (GBP,4))) . (Initialize s) is set
(Initialize s) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize s) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Initialize s) . GBP) + 5 is V11() V12() ext-real integer set
K155((((Initialize s) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize s) . GBP) + 5))] is set
{1,K155((((Initialize s) . GBP) + 5))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((((Initialize s) . GBP) + 5))},{1}} is V1() V56() V57() set
0 + 5 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 5) is Int-like Element of the U1 of SCMPDS
K397((0 + 5)) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
DataLoc (((Initialize s) . GBP),4) is Int-like Element of the U1 of SCMPDS
((Initialize s) . GBP) + 4 is V11() V12() ext-real integer set
K155((((Initialize s) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize s) . GBP) + 4))] is set
{1,K155((((Initialize s) . GBP) + 4))} is V1() set
{{1,K155((((Initialize s) . GBP) + 4))},{1}} is V1() V56() V57() set
(Initialize s) . (DataLoc (((Initialize s) . GBP),4)) is V11() V12() ext-real integer set
0 + 4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K397((0 + 4)) is Int-like Element of the U1 of K388()
(Initialize s) . (intpos (0 + 4)) is V11() V12() ext-real integer set
(Initialize s) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize s) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP),5) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 5 is V11() V12() ext-real integer set
K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 5)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 5))] is set
{1,K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 5))} is V1() set
{{1,K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 5))},{1}} is V1() V56() V57() set
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (SubFrom (GBP,5,GBP,2)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (SubFrom (GBP,5,GBP,2))) . (Exec (((GBP,5) := (GBP,4)),(Initialize s))) is set
(Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP),3) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 3 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 3))] is set
{1,K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 3))} is V1() set
{{1,K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 3))},{1}} is V1() V56() V57() set
0 + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 3) is Int-like Element of the U1 of SCMPDS
K397((0 + 3)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,3) := (GBP,2)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,3) := (GBP,2))) . (IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) is set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize s) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP),2) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 2 is V11() V12() ext-real integer set
K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 2))] is set
{1,K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 2))} is V1() set
{{1,K155((((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP) + 2))},{1}} is V1() V56() V57() set
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (DataLoc (((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP),2)) is V11() V12() ext-real integer set
((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos 5)) - ((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (DataLoc (((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . GBP),2))) is V11() V12() ext-real integer set
0 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K397((0 + 2)) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos (0 + 2)) is V11() V12() ext-real integer set
((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos 5)) - ((Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos (0 + 2))) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP),3) is Int-like Element of the U1 of SCMPDS
((IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP) + 3 is V11() V12() ext-real integer set
K155((((IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP) + 3)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP) + 3))] is set
{1,K155((((IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP) + 3))} is V1() set
{{1,K155((((IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . GBP) + 3))},{1}} is V1() V56() V57() set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 2 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 2))] is set
{1,K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 2))} is V1() set
{{1,K155((((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP) + 2))},{1}} is V1() V56() V57() set
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (DataLoc (((IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . GBP),2)) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,3,1)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,3,1))) . (IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) is set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . GBP is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . (intpos 3) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . (intpos 5) is V11() V12() ext-real integer set
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l2 is Int-like Element of the U1 of SCMPDS
K397(l2) is Int-like Element of the U1 of K388()
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
(Initialize s) . (intpos l2) is V11() V12() ext-real integer set
s . (intpos l2) is V11() V12() ext-real integer set
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l2 is Int-like Element of the U1 of SCMPDS
K397(l2) is Int-like Element of the U1 of K388()
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,5,GBP,2)),(Exec (((GBP,5) := (GBP,4)),(Initialize s))))) . (intpos l2) is V11() V12() ext-real integer set
(Exec (((GBP,5) := (GBP,4)),(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
s . (intpos l2) is V11() V12() ext-real integer set
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l2 is Int-like Element of the U1 of SCMPDS
K397(l2) is Int-like Element of the U1 of K388()
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
(Exec (((GBP,3) := (GBP,2)),(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))))) . (intpos l2) is V11() V12() ext-real integer set
(IExec ((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))),p0,(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
s . (intpos l2) is V11() V12() ext-real integer set
l2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos l2 is Int-like Element of the U1 of SCMPDS
K397(l2) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,3,1)),(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))))) . (intpos l2) is V11() V12() ext-real integer set
(IExec (((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))),p0,(Initialize s))) . (intpos l2) is V11() V12() ext-real integer set
s . (intpos l2) is V11() V12() ext-real integer set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
s +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 5) is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
(s . (intpos 4)) - (s . (intpos 2)) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 4) is V11() V12() ext-real integer set
P + ((IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 5)) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 3) is V11() V12() ext-real integer set
(s . (intpos 2)) + 1 is V11() V12() ext-real integer set
((IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . (intpos 3)) - 1 is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) . GBP is V11() V12() ext-real integer set
Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) . (intpos 5) is V11() V12() ext-real integer set
stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
l3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))),(Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))),l3) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))),(Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))),l3)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))),(Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,(Initialize s))))),l3)) . (IC ) is set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s . GBP is V11() V12() ext-real integer set
s . (intpos 4) is V11() V12() ext-real integer set
s . (intpos 2) is V11() V12() ext-real integer set
(s . (intpos 4)) - (s . (intpos 2)) is V11() V12() ext-real integer set
IExec ((),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((),p0,s)) . GBP is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
s . (intpos 1) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
pn is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len pn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len l1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
s +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . GBP is V11() V12() ext-real integer set
Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . GBP is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 3) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos 3) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 5) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos 5) is V11() V12() ext-real integer set
7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
P - p0 is V11() V12() ext-real integer set
l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + l7 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
P + ((IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 5)) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
l0 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len l0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(s . (intpos 2)) + 1 is V11() V12() ext-real integer set
((IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos 3)) - 1 is V11() V12() ext-real integer set
stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))),(Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)))),lb) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))),(Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)))),lb)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((p0 +* (stop (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))))),(Initialize (Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)))),lb)) . (IC ) is set
lb is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len lb is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
lb . L5 is V11() V12() ext-real integer set
p0 + L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + L5) is Int-like Element of the U1 of SCMPDS
K397((p0 + L5)) is Int-like Element of the U1 of K388()
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos (p0 + L5)) is V11() V12() ext-real integer set
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos (p0 + L5)) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos 4) is V11() V12() ext-real integer set
L5 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
L5 - p0 is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . GBP is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP) + 6))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
0 + 6 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 6) is Int-like Element of the U1 of SCMPDS
K397((0 + 6)) is Int-like Element of the U1 of K388()
IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
dom lb is V139() Element of K6(NAT)
Seg n is Element of K6(NAT)
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
WH4 + p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
lb . WH4 is V11() V12() ext-real integer set
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + m1) is Int-like Element of the U1 of SCMPDS
K397((p0 + m1)) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos (p0 + m1)) is V11() V12() ext-real integer set
s . (intpos (p0 + m1)) is V11() V12() ext-real integer set
pn . WH4 is V11() V12() ext-real integer set
TR is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 6) is V11() V12() ext-real integer set
Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,6) := ((intpos 4),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,6) := ((intpos 4),0))) . (IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) is set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)))) . (intpos 6) is V11() V12() ext-real integer set
DataLoc (((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)) + 0 is V11() V12() ext-real integer set
K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)) + 0))] is set
{1,K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)) + 0))} is V1() set
{{1,K155((((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)) + 0))},{1}} is V1() V56() V57() set
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (DataLoc (((IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 4)),0)) is V11() V12() ext-real integer set
L5 + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (L5 + 0) is Int-like Element of the U1 of SCMPDS
K397((L5 + 0)) is Int-like Element of the U1 of K388()
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos (L5 + 0)) is V11() V12() ext-real integer set
intpos L5 is Int-like Element of the U1 of SCMPDS
K397(L5) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
DataLoc (((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4)),0) is Int-like Element of the U1 of SCMPDS
((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4)) + 0 is V11() V12() ext-real integer set
K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4)) + 0))] is set
{1,K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4)) + 0))} is V1() set
{{1,K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 4)) + 0))},{1}} is V1() V56() V57() set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)))) . GBP is V11() V12() ext-real integer set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2) is V11() V12() ext-real integer set
Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (((intpos 4),0) := ((intpos 2),0)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (((intpos 4),0) := ((intpos 2),0))) . (IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) is set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc (((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2)),0) is Int-like Element of the U1 of SCMPDS
((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2)) + 0 is V11() V12() ext-real integer set
K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2)) + 0))] is set
{1,K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2)) + 0))} is V1() set
{{1,K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 2)) + 0))},{1}} is V1() V56() V57() set
P + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (P + 0) is Int-like Element of the U1 of SCMPDS
K397((P + 0)) is Int-like Element of the U1 of K388()
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 6) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 6) is V11() V12() ext-real integer set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . GBP is V11() V12() ext-real integer set
intpos P is Int-like Element of the U1 of SCMPDS
K397(P) is Int-like Element of the U1 of K388()
(IExec ((),p0,s)) . (intpos P) is V11() V12() ext-real integer set
Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (((intpos 2),0) := (GBP,6)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (((intpos 2),0) := (GBP,6))) . (IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) is set
(Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)))) . (intpos P) is V11() V12() ext-real integer set
DataLoc (((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP),6) is Int-like Element of the U1 of SCMPDS
((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP) + 6 is V11() V12() ext-real integer set
K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP) + 6)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP) + 6))] is set
{1,K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP) + 6))} is V1() set
{{1,K155((((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP) + 6))},{1}} is V1() V56() V57() set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (DataLoc (((IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . GBP),6)) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(Exec (((GBP,6) := ((intpos 4),0)),(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)))) . (intpos WH4) is V11() V12() ext-real integer set
(IExec (((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos WH4) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos WH4) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)))) . (intpos WH4) is V11() V12() ext-real integer set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos WH4) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
WH4 + p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l0 . WH4 is V11() V12() ext-real integer set
p0 + WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + WH4) is Int-like Element of the U1 of SCMPDS
K397((p0 + WH4)) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos (p0 + WH4)) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos (p0 + WH4)) is V11() V12() ext-real integer set
l1 . WH4 is V11() V12() ext-real integer set
p0 + TR is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
l0 . TR is V11() V12() ext-real integer set
l1 . l7 is V11() V12() ext-real integer set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)))) . GBP is V11() V12() ext-real integer set
(Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos 4) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Exec ((((intpos 4),0) := ((intpos 2),0)),(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)))) . (intpos L5) is V11() V12() ext-real integer set
DataLoc (((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)),0) is Int-like Element of the U1 of SCMPDS
((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0 is V11() V12() ext-real integer set
K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0))] is set
{1,K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0))} is V1() set
{{1,K155((((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)) + 0))},{1}} is V1() V56() V57() set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (DataLoc (((IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos 2)),0)) is V11() V12() ext-real integer set
(IExec ((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))),p0,s)) . (intpos (P + 0)) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos P) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)))) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos L5) is V11() V12() ext-real integer set
l0 . l7 is V11() V12() ext-real integer set
l1 . TR is V11() V12() ext-real integer set
(Exec ((((intpos 2),0) := (GBP,6)),(IExec (((((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))) ';' (while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1)))))))))) ';' ((GBP,6) := ((intpos 4),0))) ';' (((intpos 4),0) := ((intpos 2),0))),p0,s)))) . (intpos 4) is V11() V12() ext-real integer set
P + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
WH4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos WH4 is Int-like Element of the U1 of SCMPDS
K397(WH4) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos WH4) is V11() V12() ext-real integer set
m1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos m1 is Int-like Element of the U1 of SCMPDS
K397(m1) is Int-like Element of the U1 of K388()
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos m1) is V11() V12() ext-real integer set
(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))) . (intpos m1) is V11() V12() ext-real integer set
(IExec ((),p0,s)) . (intpos WH4) is V11() V12() ext-real integer set
(IExec ((while>0 (GBP,5,(((while>0 (GBP,5,((((((GBP,7) := (GBP,5)) ';' (AddTo (GBP,5,(- 1)))) ';' ((GBP,6) := ((intpos 4),0))) ';' (SubFrom (GBP,6,(intpos 2),0))) ';' (if>0 (GBP,6,((AddTo (GBP,4,(- 1))) ';' (AddTo (GBP,7,(- 1)))),(Load ((GBP,5) := 0))))))) ';' (while>0 (GBP,7,((((((GBP,5) := (GBP,7)) ';' (AddTo (GBP,7,(- 1)))) ';' ((GBP,6) := ((intpos 2),0))) ';' (SubFrom (GBP,6,(intpos 3),0))) ';' (if>0 (GBP,6,((AddTo (GBP,3,1)) ';' (AddTo (GBP,5,(- 1)))),(Load ((GBP,7) := 0)))))))) ';' (if>0 (GBP,5,(((((((GBP,6) := ((intpos 4),0)) ';' (((intpos 4),0) := ((intpos 3),0))) ';' (((intpos 3),0) := (GBP,6))) ';' (AddTo (GBP,5,(- 2)))) ';' (AddTo (GBP,3,1))) ';' (AddTo (GBP,4,(- 1))))))))),p0,(Initialize (IExec ((((((GBP,5) := (GBP,4)) ';' (SubFrom (GBP,5,GBP,2))) ';' ((GBP,3) := (GBP,2))) ';' (AddTo (GBP,3,1))),p0,s))))) . (intpos WH4) is V11() V12() ext-real integer set
s . (intpos WH4) is V11() V12() ext-real integer set
57 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
DataLoc (0,1) is Int-like Element of the U1 of SCMPDS
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() set
K155((0 + 1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((0 + 1))] is set
{1,K155((0 + 1))} is V1() set
{1} is V1() V56() V57() set
{{1,K155((0 + 1))},{1}} is V1() V56() V57() set
P is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(n,p0) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 + n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,(p0 + n)) := (p0 + 1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,(p0 + n),(p0 + 1)*> is set
K75(7,0,<*SBP,(p0 + n),(p0 + 1)*>) is set
((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(p0 + n) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((p0 + n) + 1)) := (p0 + n) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((p0 + n) + 1),(p0 + n)*> is set
K75(7,0,<*SBP,((p0 + n) + 1),(p0 + n)*>) is set
(((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,((p0 + n) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,2,SBP,(p0 + n)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,(p0 + n)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(GBP,4) := (SBP,((p0 + n) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' () is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(p0 + n) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(SBP,((p0 + n) + 1)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(p0 + n) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((p0 + n) + 2)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((p0 + n) + 1),(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((p0 + n) + 1),(- 1)*> is set
K75(8,0,<*SBP,((p0 + n) + 1),(- 1)*>) is set
((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((p0 + n) + 2),1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((p0 + n) + 2),1*> is set
K75(8,0,<*SBP,((p0 + n) + 2),1*>) is set
(((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card (n,p0) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (n,p0) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
IExec ((n,p0),p0,P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize P is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
P +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
(((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) shiftable V160() set
if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
(((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
7 + n is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1)))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1))))) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(4 + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n))))) + (card (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
2 + (card (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (Load (AddTo (GBP,1,(- 2)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (Load (AddTo (GBP,1,(- 2)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + (card (Load (AddTo (GBP,1,(- 2))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + (card (Load (AddTo (GBP,1,(- 2)))))) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + (((card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + (card (Load (AddTo (GBP,1,(- 2)))))) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + (((card (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((card ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + ((((card ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom s is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))))) + (card s) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((card (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))))) + (card s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(((card (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))))) + (card s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((((card (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))))) + (card s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + (((((card (((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))))) + (card s)) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + 38 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 + 38) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
((2 + 38) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(((2 + 38) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
2 + ((((2 + 38) + (card (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) + 1) + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
51 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
card ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
card (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
(card ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n)))) + (card (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
4 + (card (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
51 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
4 + (51 + 2) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) . (intpos 4) is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (i + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((i + (p0 + n))) is Int-like Element of the U1 of K388()
f . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
(i + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((i + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((i + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
f . (intpos ((i + (p0 + n)) + 1)) is V11() V12() ext-real integer set
Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,2) := (SBP,(p0 + n))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,2) := (SBP,(p0 + n)))) . (Initialize f) is set
(Initialize f) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize f) . GBP),2) is Int-like Element of the U1 of SCMPDS
((Initialize f) . GBP) + 2 is V11() V12() ext-real integer set
K155((((Initialize f) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize f) . GBP) + 2))] is set
{1,K155((((Initialize f) . GBP) + 2))} is V1() set
{{1,K155((((Initialize f) . GBP) + 2))},{1}} is V1() V56() V57() set
0 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K397((0 + 2)) is Int-like Element of the U1 of K388()
(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP) + 4 is V11() V12() ext-real integer set
K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP) + 4))] is set
{1,K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP) + 4))} is V1() set
{{1,K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . GBP) + 4))},{1}} is V1() V56() V57() set
0 + 4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K397((0 + 4)) is Int-like Element of the U1 of K388()
(Initialize f) . SBP is V11() V12() ext-real integer set
(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP is V11() V12() ext-real integer set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . (intpos ((i + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Initialize f) . (intpos ((i + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc (((Initialize f) . SBP),(p0 + n)) is Int-like Element of the U1 of SCMPDS
((Initialize f) . SBP) + (p0 + n) is V11() V12() ext-real integer set
K155((((Initialize f) . SBP) + (p0 + n))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize f) . SBP) + (p0 + n)))] is set
{1,K155((((Initialize f) . SBP) + (p0 + n)))} is V1() set
{{1,K155((((Initialize f) . SBP) + (p0 + n)))},{1}} is V1() V56() V57() set
(Initialize f) . (DataLoc (((Initialize f) . SBP),(p0 + n))) is V11() V12() ext-real integer set
(Initialize f) . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
Exec (((GBP,4) := (SBP,((p0 + n) + 1))),(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((GBP,4) := (SBP,((p0 + n) + 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,4) := (SBP,((p0 + n) + 1)))) . (Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) is set
(Exec (((GBP,4) := (SBP,((p0 + n) + 1))),(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))))) . (intpos 2) is V11() V12() ext-real integer set
(Exec (((GBP,4) := (SBP,((p0 + n) + 1))),(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))))) . (intpos 4) is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP),((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP) + ((p0 + n) + 1) is V11() V12() ext-real integer set
K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP) + ((p0 + n) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP) + ((p0 + n) + 1)))] is set
{1,K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP) + ((p0 + n) + 1)))} is V1() set
{{1,K155((((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP) + ((p0 + n) + 1)))},{1}} is V1() V56() V57() set
(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . (DataLoc (((Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . SBP),((p0 + n) + 1))) is V11() V12() ext-real integer set
y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos y1 is Int-like Element of the U1 of SCMPDS
K397(y1) is Int-like Element of the U1 of K388()
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) . (intpos y1) is V11() V12() ext-real integer set
(Exec (((GBP,4) := (SBP,((p0 + n) + 1))),(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))))) . (intpos y1) is V11() V12() ext-real integer set
(Exec (((GBP,2) := (SBP,(p0 + n))),(Initialize f))) . (intpos y1) is V11() V12() ext-real integer set
(Initialize f) . (intpos y1) is V11() V12() ext-real integer set
f . (intpos y1) is V11() V12() ext-real integer set
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f . (intpos 4) is V11() V12() ext-real integer set
(f . (intpos 4)) - 1 is V11() V12() ext-real integer set
(f . (intpos 4)) + 1 is V11() V12() ext-real integer set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . GBP is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . SBP is V11() V12() ext-real integer set
Q is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Q + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Q + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (Q + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((Q + (p0 + n))) is Int-like Element of the U1 of K388()
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
f . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 2) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 2)) is Int-like Element of the U1 of K388()
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 3) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 3)) is Int-like Element of the U1 of K388()
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
f . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1)))) . (Initialize f) is set
1 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
8 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(Q + (p0 + n)) + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Initialize f) . SBP is V11() V12() ext-real integer set
DataLoc (((Initialize f) . SBP),((p0 + n) + 3)) is Int-like Element of the U1 of SCMPDS
((Initialize f) . SBP) + ((p0 + n) + 3) is V11() V12() ext-real integer set
K155((((Initialize f) . SBP) + ((p0 + n) + 3))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize f) . SBP) + ((p0 + n) + 3)))] is set
{1,K155((((Initialize f) . SBP) + ((p0 + n) + 3)))} is V1() set
{{1,K155((((Initialize f) . SBP) + ((p0 + n) + 3)))},{1}} is V1() V56() V57() set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(Initialize f) . (intpos mp) is V11() V12() ext-real integer set
f . (intpos mp) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
8 + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP is V11() V12() ext-real integer set
DataLoc (((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP),((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + ((p0 + n) + 1) is V11() V12() ext-real integer set
K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + ((p0 + n) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + ((p0 + n) + 1)))] is set
{1,K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + ((p0 + n) + 1)))} is V1() set
{{1,K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + ((p0 + n) + 1)))},{1}} is V1() V56() V57() set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
Exec (((SBP,((p0 + n) + 1)) := (GBP,4)),(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((SBP,((p0 + n) + 1)) := (GBP,4)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((SBP,((p0 + n) + 1)) := (GBP,4))) . (Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) is set
(Exec (((SBP,((p0 + n) + 1)) := (GBP,4)),(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))))) . (intpos mp) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP),((p0 + n) + 2)) is Int-like Element of the U1 of SCMPDS
((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 2) is V11() V12() ext-real integer set
K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 2))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 2)))] is set
{1,K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 2)))} is V1() set
{{1,K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 2)))},{1}} is V1() V56() V57() set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
Exec (((SBP,((p0 + n) + 2)) := (GBP,4)),(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((SBP,((p0 + n) + 2)) := (GBP,4)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((SBP,((p0 + n) + 2)) := (GBP,4))) . (IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) is set
(Exec (((SBP,((p0 + n) + 2)) := (GBP,4)),(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
DataLoc (((Initialize f) . SBP),((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
((Initialize f) . SBP) + ((p0 + n) + 1) is V11() V12() ext-real integer set
K155((((Initialize f) . SBP) + ((p0 + n) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize f) . SBP) + ((p0 + n) + 1)))] is set
{1,K155((((Initialize f) . SBP) + ((p0 + n) + 1)))} is V1() set
{{1,K155((((Initialize f) . SBP) + ((p0 + n) + 1)))},{1}} is V1() V56() V57() set
(Initialize f) . (DataLoc (((Initialize f) . SBP),((p0 + n) + 1))) is V11() V12() ext-real integer set
Q + ((p0 + n) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (Q + ((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
K397((Q + ((p0 + n) + 1))) is Int-like Element of the U1 of K388()
(Initialize f) . (intpos (Q + ((p0 + n) + 1))) is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos 4) is V11() V12() ext-real integer set
8 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP),((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
((IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 1) is V11() V12() ext-real integer set
K155((((IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 1)))] is set
{1,K155((((IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 1)))} is V1() set
{{1,K155((((IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . SBP) + ((p0 + n) + 1)))},{1}} is V1() V56() V57() set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
Exec ((AddTo (SBP,((p0 + n) + 1),(- 1))),(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (SBP,((p0 + n) + 1),(- 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (SBP,((p0 + n) + 1),(- 1)))) . (IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) is set
(Exec ((AddTo (SBP,((p0 + n) + 1),(- 1))),(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))))) . (intpos mp) is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP),((p0 + n) + 2)) is Int-like Element of the U1 of SCMPDS
((IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP) + ((p0 + n) + 2) is V11() V12() ext-real integer set
K155((((IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP) + ((p0 + n) + 2))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP) + ((p0 + n) + 2)))] is set
{1,K155((((IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP) + ((p0 + n) + 2)))} is V1() set
{{1,K155((((IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . SBP) + ((p0 + n) + 2)))},{1}} is V1() V56() V57() set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
Exec ((AddTo (SBP,((p0 + n) + 2),1)),(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (SBP,((p0 + n) + 2),1)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (SBP,((p0 + n) + 2),1))) . (IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) is set
(Exec ((AddTo (SBP,((p0 + n) + 2),1)),(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . GBP is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . GBP is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP),1) is Int-like Element of the U1 of SCMPDS
((IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP) + 1 is V11() V12() ext-real integer set
K155((((IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP) + 1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP) + 1))] is set
{1,K155((((IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP) + 1))} is V1() set
{{1,K155((((IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . GBP) + 1))},{1}} is V1() V56() V57() set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 1) is Int-like Element of the U1 of SCMPDS
K397((0 + 1)) is Int-like Element of the U1 of K388()
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . SBP is V11() V12() ext-real integer set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
Exec ((AddTo (GBP,1,2)),(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (AddTo (GBP,1,2)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,1,2))) . (IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) is set
(Exec ((AddTo (GBP,1,2)),(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))))) . (intpos mp) is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,1,2)),(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))))) . SBP is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 2)) := (GBP,4)),(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
DataLoc (((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP) + 4 is V11() V12() ext-real integer set
K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP) + 4))] is set
{1,K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP) + 4))} is V1() set
{{1,K155((((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP) + 4))},{1}} is V1() V56() V57() set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (DataLoc (((IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . GBP),4)) is V11() V12() ext-real integer set
0 + 4 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 4) is Int-like Element of the U1 of SCMPDS
K397((0 + 4)) is Int-like Element of the U1 of K388()
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos (0 + 4)) is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 1)) := (GBP,4)),(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
DataLoc (((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP),4) is Int-like Element of the U1 of SCMPDS
((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 4 is V11() V12() ext-real integer set
K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 4)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 4))] is set
{1,K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 4))} is V1() set
{{1,K155((((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 4))},{1}} is V1() V56() V57() set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (DataLoc (((Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP),4)) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos (0 + 4)) is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Exec ((AddTo (SBP,((p0 + n) + 1),(- 1))),(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(f . (intpos 4)) + (- 1) is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
(Exec ((AddTo (SBP,((p0 + n) + 2),1)),(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
mp is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos mp is Int-like Element of the U1 of SCMPDS
K397(mp) is Int-like Element of the U1 of K388()
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec (((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(IExec ((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))),g,(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos mp) is V11() V12() ext-real integer set
f . (intpos mp) is V11() V12() ext-real integer set
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . GBP is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos 1) is V11() V12() ext-real integer set
Q is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Q + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (Q + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((Q + (p0 + n))) is Int-like Element of the U1 of K388()
f . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Q + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
f . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
Q + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 3) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 3)) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 2) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 2)) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
f2 is V11() V12() ext-real integer set
f2 - f1 is V11() V12() ext-real integer set
k1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . GBP is V11() V12() ext-real integer set
Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . GBP is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos 2) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos 4) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos 4) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos 1) is V11() V12() ext-real integer set
IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k1 . i is V11() V12() ext-real integer set
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K397((p0 + i)) is Int-like Element of the U1 of K388()
f . (intpos (p0 + i)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos (p0 + i)) is V11() V12() ext-real integer set
i is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k1 . a is V11() V12() ext-real integer set
p0 + a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + a) is Int-like Element of the U1 of SCMPDS
K397((p0 + a)) is Int-like Element of the U1 of K388()
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos (p0 + a)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos (p0 + a)) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos 4) is V11() V12() ext-real integer set
a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos a is Int-like Element of the U1 of SCMPDS
K397(a) is Int-like Element of the U1 of K388()
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos a) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . GBP is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . GBP is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . SBP is V11() V12() ext-real integer set
Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . GBP is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . SBP is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos 4) is V11() V12() ext-real integer set
((IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos 4)) + 1 is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
((IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos 4)) - 1 is V11() V12() ext-real integer set
1 + (p0 + n) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
dom k2 is V139() Element of K6(NAT)
Seg n is Element of K6(NAT)
ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
p0 + ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 . ym is V11() V12() ext-real integer set
j is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + j is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + j) is Int-like Element of the U1 of SCMPDS
K397((p0 + j)) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos (p0 + j)) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos (p0 + j)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos (p0 + j)) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos (p0 + j)) is V11() V12() ext-real integer set
i . ym is V11() V12() ext-real integer set
1 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
8 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + n) + ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((p0 + n) + ym) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + ym)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
f . (intpos ((p0 + n) + ym)) is V11() V12() ext-real integer set
a - 1 is V11() V12() ext-real integer set
a + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos a) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos a) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos a) is V11() V12() ext-real integer set
ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ym is Int-like Element of the U1 of SCMPDS
K397(ym) is Int-like Element of the U1 of K388()
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos ym) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos ym) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ym) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ym) is V11() V12() ext-real integer set
ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ym is Int-like Element of the U1 of SCMPDS
K397(ym) is Int-like Element of the U1 of K388()
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos ym) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos ym) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ym) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ym) is V11() V12() ext-real integer set
ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ym is Int-like Element of the U1 of SCMPDS
K397(ym) is Int-like Element of the U1 of K388()
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f)) . (intpos ym) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))) . (intpos ym) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,f)) . (intpos ym) is V11() V12() ext-real integer set
(IExec ((((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))),g,(Initialize (IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f))))) . (intpos ym) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s),g,f)) . (intpos ym) is V11() V12() ext-real integer set
(IExec (s,g,(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,f))))) . (intpos ym) is V11() V12() ext-real integer set
f . (intpos ym) is V11() V12() ext-real integer set
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,(Initialize f))) . (intpos 2) is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(i + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((i + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((i + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
f . (intpos ((i + (p0 + n)) + 1)) is V11() V12() ext-real integer set
intpos (i + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((i + (p0 + n))) is Int-like Element of the U1 of K388()
f . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
(f . (intpos ((i + (p0 + n)) + 1))) - (f . (intpos (i + (p0 + n)))) is V11() V12() ext-real integer set
Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . ((GBP,2) := (SBP,((p0 + n) + 1))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((GBP,2) := (SBP,((p0 + n) + 1)))) . (Initialize f) is set
(Initialize f) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize f) . GBP),2) is Int-like Element of the U1 of SCMPDS
((Initialize f) . GBP) + 2 is V11() V12() ext-real integer set
K155((((Initialize f) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize f) . GBP) + 2))] is set
{1,K155((((Initialize f) . GBP) + 2))} is V1() set
{{1,K155((((Initialize f) . GBP) + 2))},{1}} is V1() V56() V57() set
0 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K397((0 + 2)) is Int-like Element of the U1 of K388()
(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP),2) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 2 is V11() V12() ext-real integer set
K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 2))] is set
{1,K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 2))} is V1() set
{{1,K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . GBP) + 2))},{1}} is V1() V56() V57() set
(Initialize f) . SBP is V11() V12() ext-real integer set
(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP is V11() V12() ext-real integer set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
(Initialize f) . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc (((Initialize f) . SBP),((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
((Initialize f) . SBP) + ((p0 + n) + 1) is V11() V12() ext-real integer set
K155((((Initialize f) . SBP) + ((p0 + n) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize f) . SBP) + ((p0 + n) + 1)))] is set
{1,K155((((Initialize f) . SBP) + ((p0 + n) + 1)))} is V1() set
{{1,K155((((Initialize f) . SBP) + ((p0 + n) + 1)))},{1}} is V1() V56() V57() set
(Initialize f) . (DataLoc (((Initialize f) . SBP),((p0 + n) + 1))) is V11() V12() ext-real integer set
i + ((p0 + n) + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (i + ((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
K397((i + ((p0 + n) + 1))) is Int-like Element of the U1 of K388()
(Initialize f) . (intpos (i + ((p0 + n) + 1))) is V11() V12() ext-real integer set
Exec ((SubFrom (GBP,2,SBP,(p0 + n))),(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (SubFrom (GBP,2,SBP,(p0 + n))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (SubFrom (GBP,2,SBP,(p0 + n)))) . (Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) is set
(Exec ((SubFrom (GBP,2,SBP,(p0 + n))),(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))))) . (intpos 2) is V11() V12() ext-real integer set
DataLoc (((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP),(p0 + n)) is Int-like Element of the U1 of SCMPDS
((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + (p0 + n) is V11() V12() ext-real integer set
K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + (p0 + n))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + (p0 + n)))] is set
{1,K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + (p0 + n)))} is V1() set
{{1,K155((((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP) + (p0 + n)))},{1}} is V1() V56() V57() set
(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . (DataLoc (((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP),(p0 + n))) is V11() V12() ext-real integer set
((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos 2)) - ((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . (DataLoc (((Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . SBP),(p0 + n)))) is V11() V12() ext-real integer set
k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos k2 is Int-like Element of the U1 of SCMPDS
K397(k2) is Int-like Element of the U1 of K388()
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,(Initialize f))) . (intpos k2) is V11() V12() ext-real integer set
(Exec ((SubFrom (GBP,2,SBP,(p0 + n))),(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))))) . (intpos k2) is V11() V12() ext-real integer set
(Exec (((GBP,2) := (SBP,((p0 + n) + 1))),(Initialize f))) . (intpos k2) is V11() V12() ext-real integer set
(Initialize f) . (intpos k2) is V11() V12() ext-real integer set
f . (intpos k2) is V11() V12() ext-real integer set
7 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . GBP is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos 1) is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(i + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((i + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((i + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
f . (intpos ((i + (p0 + n)) + 1)) is V11() V12() ext-real integer set
intpos (i + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((i + (p0 + n))) is Int-like Element of the U1 of K388()
f . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
i - 2 is V11() V12() ext-real integer set
IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos 2) is V11() V12() ext-real integer set
(f . (intpos ((i + (p0 + n)) + 1))) - (f . (intpos (i + (p0 + n)))) is V11() V12() ext-real integer set
Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2))] is set
{1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2))} is V1() set
{{1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2))},{1}} is V1() V56() V57() set
0 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K397((0 + 2)) is Int-like Element of the U1 of K388()
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP is V11() V12() ext-real integer set
DataLoc (((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP),1) is Int-like Element of the U1 of SCMPDS
((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP) + 1 is V11() V12() ext-real integer set
K155((((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP) + 1)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP) + 1))] is set
{1,K155((((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP) + 1))} is V1() set
{{1,K155((((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP) + 1))},{1}} is V1() V56() V57() set
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 1) is Int-like Element of the U1 of SCMPDS
K397((0 + 1)) is Int-like Element of the U1 of K388()
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP),2)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP),2)) is V11() V12() ext-real integer set
y1 is Int-like Element of the U1 of SCMPDS
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . y1 is V11() V12() ext-real integer set
IExec ((if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . y1 is V11() V12() ext-real integer set
IExec ((Load (AddTo (GBP,1,(- 2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((Load (AddTo (GBP,1,(- 2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . y1 is V11() V12() ext-real integer set
Exec ((AddTo (GBP,1,(- 2))),(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . (AddTo (GBP,1,(- 2))) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (AddTo (GBP,1,(- 2)))) . (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) is set
(Exec ((AddTo (GBP,1,(- 2))),(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . y1 is V11() V12() ext-real integer set
y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos y1 is Int-like Element of the U1 of SCMPDS
K397(y1) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos y1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,1,(- 2))),(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos y1) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos y1) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos y1) is V11() V12() ext-real integer set
(Exec ((AddTo (GBP,1,(- 2))),(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos 1) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos 1) is V11() V12() ext-real integer set
((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos 1)) + (- 2) is V11() V12() ext-real integer set
((Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos 1)) - 2 is V11() V12() ext-real integer set
y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + n) + y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((p0 + n) + y1) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + y1)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos ((p0 + n) + y1)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos ((p0 + n) + y1)) is V11() V12() ext-real integer set
f . (intpos ((p0 + n) + y1)) is V11() V12() ext-real integer set
y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + y1) is Int-like Element of the U1 of SCMPDS
K397((p0 + y1)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos (p0 + y1)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos (p0 + y1)) is V11() V12() ext-real integer set
f . (intpos (p0 + y1)) is V11() V12() ext-real integer set
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (i + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((i + (p0 + n))) is Int-like Element of the U1 of K388()
f . (intpos (i + (p0 + n))) is V11() V12() ext-real integer set
Q is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(i + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((i + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((i + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
f . (intpos ((i + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(f . (intpos ((i + (p0 + n)) + 1))) - Q is V11() V12() ext-real integer set
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) . GBP is V11() V12() ext-real integer set
Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f)))) . GBP is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f))) . (intpos 2) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))),g,(Initialize f)))) . (intpos 2) is V11() V12() ext-real integer set
f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f . GBP is V11() V12() ext-real integer set
f . SBP is V11() V12() ext-real integer set
g is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . GBP is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos 1) is V11() V12() ext-real integer set
Q is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
Q + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (Q + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((Q + (p0 + n))) is Int-like Element of the U1 of K388()
f . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Q + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
f . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
Q + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 3) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 3)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(Q + (p0 + n)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((Q + (p0 + n)) + 2) is Int-like Element of the U1 of SCMPDS
K397(((Q + (p0 + n)) + 2)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
f2 is V11() V12() ext-real integer set
f2 - f1 is V11() V12() ext-real integer set
k1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Initialize f is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
f +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos 2) is V11() V12() ext-real integer set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k1 . md is V11() V12() ext-real integer set
intpos (p0 + md) is Int-like Element of the U1 of SCMPDS
K397((p0 + md)) is Int-like Element of the U1 of K388()
f . (intpos (p0 + md)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos (p0 + md)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2))] is set
{1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2))} is V1() set
{{1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP) + 2))},{1}} is V1() V56() V57() set
0 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K397((0 + 2)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . SBP is V11() V12() ext-real integer set
Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
g +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP),2)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . GBP),2)) is V11() V12() ext-real integer set
stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
g +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((g +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))),md) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((g +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))),md)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((g +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))),md)) . (IC ) is set
stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
g +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
g +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((g +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))),md) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((g +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))),md)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((g +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))),md)) . (IC ) is set
md is Int-like Element of the U1 of SCMPDS
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . md is V11() V12() ext-real integer set
IExec ((if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . md is V11() V12() ext-real integer set
IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . md is V11() V12() ext-real integer set
md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k2 . md is V11() V12() ext-real integer set
p0 + md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + md) is Int-like Element of the U1 of SCMPDS
K397((p0 + md)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos (p0 + md)) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos (p0 + md)) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . SBP is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
k1 . md is V11() V12() ext-real integer set
p0 + md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + md) is Int-like Element of the U1 of SCMPDS
K397((p0 + md)) is Int-like Element of the U1 of K388()
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos (p0 + md)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos (p0 + md)) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . GBP is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos ((Q + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos ((Q + (p0 + n)) + 2)) is V11() V12() ext-real integer set
md is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
md - 1 is V11() V12() ext-real integer set
md + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos md is Int-like Element of the U1 of SCMPDS
K397(md) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos md) is V11() V12() ext-real integer set
n4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos n4 is Int-like Element of the U1 of SCMPDS
K397(n4) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos n4) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos n4) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos n4) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos 1) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos (Q + (p0 + n))) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos ((Q + (p0 + n)) + 3)) is V11() V12() ext-real integer set
n4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + n) + n4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((p0 + n) + n4) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + n4)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos ((p0 + n) + n4)) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos ((p0 + n) + n4)) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))) . (intpos ((p0 + n) + n4)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos ((p0 + n) + n4)) is V11() V12() ext-real integer set
f . (intpos ((p0 + n) + n4)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos md) is V11() V12() ext-real integer set
n4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos n4 is Int-like Element of the U1 of SCMPDS
K397(n4) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos n4) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos n4) is V11() V12() ext-real integer set
n4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos n4 is Int-like Element of the U1 of SCMPDS
K397(n4) is Int-like Element of the U1 of K388()
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos n4) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos n4) is V11() V12() ext-real integer set
n4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos n4 is Int-like Element of the U1 of SCMPDS
K397(n4) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),g,f)) . (intpos n4) is V11() V12() ext-real integer set
(IExec ((((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),g,(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f))))) . (intpos n4) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),g,f)) . (intpos n4) is V11() V12() ext-real integer set
f . (intpos n4) is V11() V12() ext-real integer set
f is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len f is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
7 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . GBP is V11() V12() ext-real integer set
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos 1) is V11() V12() ext-real integer set
intpos ((p0 + n) + 1) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + 1)) is Int-like Element of the U1 of K388()
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos ((p0 + n) + 1)) is V11() V12() ext-real integer set
intpos ((p0 + n) + 2) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + 2)) is Int-like Element of the U1 of K388()
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos ((p0 + n) + 2)) is V11() V12() ext-real integer set
IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IExec (((GBP := 0) ';' (SBP := 1)),p0,P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
Exec ((GBP := 0),P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS) is set
K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) is set
the Execution of SCMPDS is Relation-like the InstructionsF of SCMPDS -defined K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))) -valued Function-like V27( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) Element of K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))))
K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))) is Relation-like set
K6(K7( the InstructionsF of SCMPDS,K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS))))) is set
the Execution of SCMPDS . (GBP := 0) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (GBP := 0)) . P is set
(Exec ((GBP := 0),P)) . GBP is V11() V12() ext-real integer set
(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . GBP is V11() V12() ext-real integer set
Exec ((SBP := 1),(Exec ((GBP := 0),P))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . (SBP := 1) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . (SBP := 1)) . (Exec ((GBP := 0),P)) is set
(Exec ((SBP := 1),(Exec ((GBP := 0),P)))) . GBP is V11() V12() ext-real integer set
(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP is V11() V12() ext-real integer set
(Exec ((SBP := 1),(Exec ((GBP := 0),P)))) . SBP is V11() V12() ext-real integer set
DataLoc (((IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP),(p0 + n)) is Int-like Element of the U1 of SCMPDS
((IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP) + (p0 + n) is V11() V12() ext-real integer set
K155((((IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP) + (p0 + n))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP) + (p0 + n)))] is set
{1,K155((((IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP) + (p0 + n)))} is V1() set
{{1,K155((((IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . SBP) + (p0 + n)))},{1}} is V1() V56() V57() set
(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . GBP is V11() V12() ext-real integer set
Exec (((SBP,(p0 + n)) := (p0 + 1)),(IExec (((GBP := 0) ';' (SBP := 1)),p0,P))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((SBP,(p0 + n)) := (p0 + 1)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((SBP,(p0 + n)) := (p0 + 1))) . (IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) is set
(Exec (((SBP,(p0 + n)) := (p0 + 1)),(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)))) . GBP is V11() V12() ext-real integer set
(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . (intpos ((p0 + n) + 1)) is V11() V12() ext-real integer set
(Exec (((SBP,(p0 + n)) := (p0 + 1)),(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)))) . (intpos ((p0 + n) + 1)) is V11() V12() ext-real integer set
(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP is V11() V12() ext-real integer set
(Exec (((SBP,(p0 + n)) := (p0 + 1)),(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)))) . SBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP),((p0 + n) + 1)) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP) + ((p0 + n) + 1) is V11() V12() ext-real integer set
K155((((IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP) + ((p0 + n) + 1))) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP) + ((p0 + n) + 1)))] is set
{1,K155((((IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP) + ((p0 + n) + 1)))} is V1() set
{{1,K155((((IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . SBP) + ((p0 + n) + 1)))},{1}} is V1() V56() V57() set
1 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(p0 + n) + (1 + 1) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((p0 + n) + (1 + 1)) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + (1 + 1))) is Int-like Element of the U1 of K388()
Exec (((SBP,((p0 + n) + 1)) := (p0 + n)),(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
the Execution of SCMPDS . ((SBP,((p0 + n) + 1)) := (p0 + n)) is Element of K103((product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)),(product ( the Object-Kind of SCMPDS (#) the ValuesF of SCMPDS)))
( the Execution of SCMPDS . ((SBP,((p0 + n) + 1)) := (p0 + n))) . (IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) is set
(Exec (((SBP,((p0 + n) + 1)) := (p0 + n)),(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)))) . GBP is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 1)) := (p0 + n)),(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)))) . SBP is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 1)) := (p0 + n)),(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)))) . (intpos ((p0 + n) + 1)) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 1)) := (p0 + n)),(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)))) . (intpos ((p0 + n) + 2)) is V11() V12() ext-real integer set
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos f1 is Int-like Element of the U1 of SCMPDS
K397(f1) is Int-like Element of the U1 of K388()
(Exec ((GBP := 0),P)) . (intpos f1) is V11() V12() ext-real integer set
P . (intpos f1) is V11() V12() ext-real integer set
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos f1 is Int-like Element of the U1 of SCMPDS
K397(f1) is Int-like Element of the U1 of K388()
(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . (intpos f1) is V11() V12() ext-real integer set
(Exec ((SBP := 1),(Exec ((GBP := 0),P)))) . (intpos f1) is V11() V12() ext-real integer set
(Exec ((GBP := 0),P)) . (intpos f1) is V11() V12() ext-real integer set
P . (intpos f1) is V11() V12() ext-real integer set
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos f1 is Int-like Element of the U1 of SCMPDS
K397(f1) is Int-like Element of the U1 of K388()
(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . (intpos f1) is V11() V12() ext-real integer set
(Exec (((SBP,(p0 + n)) := (p0 + 1)),(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)))) . (intpos f1) is V11() V12() ext-real integer set
(IExec (((GBP := 0) ';' (SBP := 1)),p0,P)) . (intpos f1) is V11() V12() ext-real integer set
P . (intpos f1) is V11() V12() ext-real integer set
(p0 + n) + 0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos f1 is Int-like Element of the U1 of SCMPDS
K397(f1) is Int-like Element of the U1 of K388()
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos f1) is V11() V12() ext-real integer set
P . (intpos f1) is V11() V12() ext-real integer set
(Exec (((SBP,((p0 + n) + 1)) := (p0 + n)),(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)))) . (intpos f1) is V11() V12() ext-real integer set
(IExec ((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))),p0,P)) . (intpos f1) is V11() V12() ext-real integer set
g is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + g is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
f . g is V11() V12() ext-real integer set
intpos (p0 + g) is Int-like Element of the U1 of SCMPDS
K397((p0 + g)) is Int-like Element of the U1 of K388()
P . (intpos (p0 + g)) is V11() V12() ext-real integer set
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos (p0 + g)) is V11() V12() ext-real integer set
g is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len g is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 1) is Int-like Element of the U1 of SCMPDS
K397((0 + 1)) is Int-like Element of the U1 of K388()
i is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
i . GBP is V11() V12() ext-real integer set
i . SBP is V11() V12() ext-real integer set
Q is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
f1 + (p0 + n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (f1 + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((f1 + (p0 + n))) is Int-like Element of the U1 of K388()
i . (intpos (f1 + (p0 + n))) is V11() V12() ext-real integer set
f2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(f1 + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((f1 + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((f1 + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
i . (intpos ((f1 + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(i . (intpos ((f1 + (p0 + n)) + 1))) - f2 is V11() V12() ext-real integer set
Initialize i is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (intpos 2) is V11() V12() ext-real integer set
(i . (intpos ((f1 + (p0 + n)) + 1))) - (i . (intpos (f1 + (p0 + n)))) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP is V11() V12() ext-real integer set
DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP),2) is Int-like Element of the U1 of SCMPDS
((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP) + 2 is V11() V12() ext-real integer set
K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP) + 2)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
[1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP) + 2))] is set
{1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP) + 2))} is V1() set
{{1,K155((((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP) + 2))},{1}} is V1() V56() V57() set
0 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (0 + 2) is Int-like Element of the U1 of SCMPDS
K397((0 + 2)) is Int-like Element of the U1 of K388()
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP),2)) is V11() V12() ext-real integer set
0 + 7 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (intpos ((f1 + (p0 + n)) + 1)) is V11() V12() ext-real integer set
((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (intpos ((f1 + (p0 + n)) + 1))) - f2 is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . SBP is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (intpos (f1 + (p0 + n))) is V11() V12() ext-real integer set
Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP),2)) is V11() V12() ext-real integer set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) . GBP is V11() V12() ext-real integer set
stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Q +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) shiftable V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Q +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
yn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((Q +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))))),yn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((Q +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))))),yn)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((Q +* (stop (((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))))),yn)) . (IC ) is set
stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Q +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
Q +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i)))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
yn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((Q +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))))),yn) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((Q +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))))),yn)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((Q +* (stop (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))),(Initialize (Initialize (IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))))),yn)) . (IC ) is set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP),2)) is V11() V12() ext-real integer set
(IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . (DataLoc (((IExec ((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))),Q,(Initialize i))) . GBP),2)) is V11() V12() ext-real integer set
k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
2 * k1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(2 * k1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + y1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
yn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + yn is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i . GBP is V11() V12() ext-real integer set
i . (DataLoc (0,1)) is V11() V12() ext-real integer set
k2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + n) + (2 * k1) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
((p0 + n) + (2 * k1)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos k2 is Int-like Element of the U1 of SCMPDS
K397(k2) is Int-like Element of the U1 of K388()
i . (intpos k2) is V11() V12() ext-real integer set
k2 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (k2 + 1) is Int-like Element of the U1 of SCMPDS
K397((k2 + 1)) is Int-like Element of the U1 of K388()
i . (intpos (k2 + 1)) is V11() V12() ext-real integer set
((2 * k1) + 1) + (p0 + n) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (((2 * k1) + 1) + (p0 + n)) is Int-like Element of the U1 of SCMPDS
K397((((2 * k1) + 1) + (p0 + n))) is Int-like Element of the U1 of K388()
i . (intpos (((2 * k1) + 1) + (p0 + n))) is V11() V12() ext-real integer set
(((2 * k1) + 1) + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((((2 * k1) + 1) + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((((2 * k1) + 1) + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
i . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(i . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1))) - (p0 + y1) is V11() V12() ext-real integer set
(((2 * k1) + 1) + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((((2 * k1) + 1) + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((((2 * k1) + 1) + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
i . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(i . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1))) - (p0 + y1) is V11() V12() ext-real integer set
(((2 * k1) + 1) + (p0 + n)) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((((2 * k1) + 1) + (p0 + n)) + 1) is Int-like Element of the U1 of SCMPDS
K397(((((2 * k1) + 1) + (p0 + n)) + 1)) is Int-like Element of the U1 of K388()
i . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(i . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1))) - (p0 + y1) is V11() V12() ext-real integer set
Q is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
f3 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len f3 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
f4 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len f4 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . GBP is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + n) + i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((p0 + n) + i) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + i)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos ((p0 + n) + i)) is V11() V12() ext-real integer set
i . (intpos ((p0 + n) + i)) is V11() V12() ext-real integer set
(p0 + yn) - (p0 + y1) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . GBP is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0 + n) + i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos ((p0 + n) + i) is Int-like Element of the U1 of SCMPDS
K397(((p0 + n) + i)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos ((p0 + n) + i)) is V11() V12() ext-real integer set
i . (intpos ((p0 + n) + i)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . GBP is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . GBP is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (DataLoc (0,1)) is V11() V12() ext-real integer set
((2 * k1) + 1) - 2 is V11() V12() ext-real integer set
(2 * k1) - 1 is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K397((p0 + i)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (p0 + i)) is V11() V12() ext-real integer set
i . (intpos (p0 + i)) is V11() V12() ext-real integer set
(p0 + yn) - (p0 + y1) is V11() V12() ext-real integer set
((2 * k1) + 1) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(2 * k1) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos ((((2 * k1) + 1) + (p0 + n)) + 1)) is V11() V12() ext-real integer set
(((2 * k1) + 1) + (p0 + n)) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos ((((2 * k1) + 1) + (p0 + n)) + 2) is Int-like Element of the U1 of SCMPDS
K397(((((2 * k1) + 1) + (p0 + n)) + 2)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos ((((2 * k1) + 1) + (p0 + n)) + 2)) is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
i - 1 is V11() V12() ext-real integer set
i + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos i is Int-like Element of the U1 of SCMPDS
K397(i) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos i) is V11() V12() ext-real integer set
a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + a) is Int-like Element of the U1 of SCMPDS
K397((p0 + a)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (p0 + a)) is V11() V12() ext-real integer set
i . (intpos (p0 + a)) is V11() V12() ext-real integer set
i - p0 is V11() V12() ext-real integer set
a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + ym is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos k2) is V11() V12() ext-real integer set
(p0 + ym) - 1 is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (k2 + 1)) is V11() V12() ext-real integer set
(p0 + ym) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
k2 + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (k2 + 2) is Int-like Element of the U1 of SCMPDS
K397((k2 + 2)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (k2 + 2)) is V11() V12() ext-real integer set
k2 + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (k2 + 3) is Int-like Element of the U1 of SCMPDS
K397((k2 + 3)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (k2 + 3)) is V11() V12() ext-real integer set
j is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + j is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + j) is Int-like Element of the U1 of SCMPDS
K397((p0 + j)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (p0 + j)) is V11() V12() ext-real integer set
intpos (p0 + ym) is Int-like Element of the U1 of SCMPDS
K397((p0 + ym)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (p0 + ym)) is V11() V12() ext-real integer set
j is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + j is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + j) is Int-like Element of the U1 of SCMPDS
K397((p0 + j)) is Int-like Element of the U1 of K388()
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (p0 + j)) is V11() V12() ext-real integer set
f1 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
f2 is Relation-like NAT -defined INT -valued Function-like V33() V34() V35() FinSequence-like FinSequence of INT
len f1 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
len f2 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom f1 is V139() Element of K6(NAT)
Seg n is Element of K6(NAT)
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer set
f1 . i is V11() V12() ext-real integer set
a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + a is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + a) is Int-like Element of the U1 of SCMPDS
K397((p0 + a)) is Int-like Element of the U1 of K388()
i . (intpos (p0 + a)) is V11() V12() ext-real integer set
(IExec (((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))),Q,i)) . (intpos (p0 + a)) is V11() V12() ext-real integer set
f2 . i is V11() V12() ext-real integer set
Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) . GBP is V11() V12() ext-real integer set
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) . (intpos ((p0 + n) + 1)) is V11() V12() ext-real integer set
((p0 + n) + 1) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
intpos (((p0 + n) + 1) + 1) is Int-like Element of the U1 of SCMPDS
K397((((p0 + n) + 1) + 1)) is Int-like Element of the U1 of K388()
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) . (intpos (((p0 + n) + 1) + 1)) is V11() V12() ext-real integer set
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos (((p0 + n) + 1) + 1)) is V11() V12() ext-real integer set
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) . (DataLoc (0,1)) is V11() V12() ext-real integer set
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (DataLoc (0,1)) is V11() V12() ext-real integer set
stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
dom (stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
Comput ((p0 +* (stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))))),(Initialize (Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)))),i) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
IC (Comput ((p0 +* (stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))))),(Initialize (Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)))),i)) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(Comput ((p0 +* (stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))))),(Initialize (Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)))),i)) . (IC ) is set
stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V98( SCMPDS ) V160() set
K343(SCMPDS) is V1() V2() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like constant V45() V88() non halt-free V97( SCMPDS ) V98( SCMPDS ) paraclosed parahalting shiftable V160() set
halt SCMPDS is V107(2, SCMPDS ) parahalting Element of the InstructionsF of SCMPDS
K339( the InstructionsF of SCMPDS) is V92( the InstructionsF of SCMPDS) Element of the InstructionsF of SCMPDS
Load is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() 1 -element V88() V160() set
K385(0,(halt SCMPDS)) is V1() V2() Relation-like NAT -defined {0} -defined the InstructionsF of SCMPDS -valued Function-like one-to-one constant set
K376({0},(halt SCMPDS)) is V1() Relation-like {0} -defined the InstructionsF of SCMPDS -valued {(halt SCMPDS)} -valued Function-like constant V23({0}) V27({0},{(halt SCMPDS)}) Element of K6(K7({0},{(halt SCMPDS)}))
{(halt SCMPDS)} is V1() set
K7({0},{(halt SCMPDS)}) is Relation-like set
K6(K7({0},{(halt SCMPDS)})) is set
(while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) ';' K343(SCMPDS) is T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 +* (stop (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))) is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize (Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
g . i is V11() V12() ext-real integer set
((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) V160() set
IExec ((((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))),p0,P) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
p0 + i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K397((p0 + i)) is Int-like Element of the U1 of K388()
(IExec ((((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))))),p0,P)) . (intpos (p0 + i)) is V11() V12() ext-real integer set
IExec ((while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))),p0,(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)))) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
(IExec ((while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' s) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))),p0,(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))))) . (intpos (p0 + i)) is V11() V12() ext-real integer set
i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
f . i is V11() V12() ext-real integer set
p0 + i is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
intpos (p0 + i) is Int-like Element of the U1 of SCMPDS
K397((p0 + i)) is Int-like Element of the U1 of K388()
(Initialize (IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P))) . (intpos (p0 + i)) is V11() V12() ext-real integer set
(IExec (((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))),p0,P)) . (intpos (p0 + i)) is V11() V12() ext-real integer set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(p0,n) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
n + p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,(n + p0)) := (n + 1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,(n + p0),(n + 1)*> is set
K75(7,0,<*SBP,(n + p0),(n + 1)*>) is set
((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(n + p0)) := (n + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(n + p0) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((n + p0) + 1)) := (n + p0) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((n + p0) + 1),(n + p0)*> is set
K75(7,0,<*SBP,((n + p0) + 1),(n + p0)*>) is set
(((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(n + p0)) := (n + 1))) ';' ((SBP,((n + p0) + 1)) := (n + p0)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,((n + p0) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,2,SBP,(n + p0)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,((n + p0) + 1))) ';' (SubFrom (GBP,2,SBP,(n + p0))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,(n + p0)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(GBP,4) := (SBP,((n + p0) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1)))) ';' () is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(n + p0) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(SBP,((n + p0) + 1)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(n + p0) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((n + p0) + 2)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((n + p0) + 1),(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((n + p0) + 1),(- 1)*> is set
K75(8,0,<*SBP,((n + p0) + 1),(- 1)*>) is set
((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((n + p0) + 2),1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((n + p0) + 2),1*> is set
K75(8,0,<*SBP,((n + p0) + 2),1*>) is set
(((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1))) ';' (AddTo (GBP,1,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1)))) ';' ()) ';' (((((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
if>0 (GBP,2,(((((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1)))) ';' ()) ';' (((((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((GBP,2) := (SBP,((n + p0) + 1))) ';' (SubFrom (GBP,2,SBP,(n + p0)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1)))) ';' ()) ';' (((((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
while>0 (GBP,1,((((GBP,2) := (SBP,((n + p0) + 1))) ';' (SubFrom (GBP,2,SBP,(n + p0)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1)))) ';' ()) ';' (((((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(n + p0)) := (n + 1))) ';' ((SBP,((n + p0) + 1)) := (n + p0))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((n + p0) + 1))) ';' (SubFrom (GBP,2,SBP,(n + p0)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(n + p0))) ';' ((GBP,4) := (SBP,((n + p0) + 1)))) ';' ()) ';' (((((((SBP,((n + p0) + 3)) := (SBP,((n + p0) + 1))) ';' ((SBP,((n + p0) + 1)) := (GBP,4))) ';' ((SBP,((n + p0) + 2)) := (GBP,4))) ';' (AddTo (SBP,((n + p0) + 1),(- 1)))) ';' (AddTo (SBP,((n + p0) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
card (p0,n) is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
dom (p0,n) is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() V139() set
p0 is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
(n,p0) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 + n is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
p0 + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,(p0 + n)) := (p0 + 1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,(p0 + n),(p0 + 1)*> is set
K75(7,0,<*SBP,(p0 + n),(p0 + 1)*>) is set
((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(p0 + n) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((p0 + n) + 1)) := (p0 + n) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((p0 + n) + 1),(p0 + n)*> is set
K75(7,0,<*SBP,((p0 + n) + 1),(p0 + n)*>) is set
(((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,((p0 + n) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,2,SBP,(p0 + n)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,(p0 + n)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(GBP,4) := (SBP,((p0 + n) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' () is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(p0 + n) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(SBP,((p0 + n) + 1)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(p0 + n) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((p0 + n) + 2)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((p0 + n) + 1),(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((p0 + n) + 1),(- 1)*> is set
K75(8,0,<*SBP,((p0 + n) + 1),(- 1)*>) is set
((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((p0 + n) + 2),1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((p0 + n) + 2),1*> is set
K75(8,0,<*SBP,((p0 + n) + 2),1*>) is set
(((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(p0 + n)) := (p0 + 1))) ';' ((SBP,((p0 + n) + 1)) := (p0 + n))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((p0 + n) + 1))) ';' (SubFrom (GBP,2,SBP,(p0 + n)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(p0 + n))) ';' ((GBP,4) := (SBP,((p0 + n) + 1)))) ';' ()) ';' (((((((SBP,((p0 + n) + 3)) := (SBP,((p0 + n) + 1))) ';' ((SBP,((p0 + n) + 1)) := (GBP,4))) ';' ((SBP,((p0 + n) + 2)) := (GBP,4))) ';' (AddTo (SBP,((p0 + n) + 1),(- 1)))) ';' (AddTo (SBP,((p0 + n) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set
P is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
Initialize s is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
Start-At (0,SCMPDS) is V1() Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V45() 0 -started V160() set
K385((IC ),0) is V1() V2() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued Function-like one-to-one constant V33() V34() V35() V36() V37() V38() V39() V40() V111() V112() set
{(IC )} is V1() set
K376({(IC )},0) is V1() Relation-like {(IC )} -defined NAT -valued RAT -valued INT -valued {0} -valued Function-like constant V23({(IC )}) V27({(IC )},{0}) V33() V34() V35() V36() V111() V112() Element of K6(K7({(IC )},{0}))
K7({(IC )},{0}) is Relation-like set
K6(K7({(IC )},{0})) is set
s +* (Start-At (0,SCMPDS)) is V1() Relation-like the U1 of SCMPDS -defined the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
s is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
n is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) 0 -started set
(P,s) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
s + P is epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real non negative integer Element of NAT
s + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,(s + P)) := (s + 1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,(s + P),(s + 1)*> is set
K75(7,0,<*SBP,(s + P),(s + 1)*>) is set
((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(s + P)) := (s + 1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(s + P) + 1 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((s + P) + 1)) := (s + P) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((s + P) + 1),(s + P)*> is set
K75(7,0,<*SBP,((s + P) + 1),(s + P)*>) is set
(((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(s + P)) := (s + 1))) ';' ((SBP,((s + P) + 1)) := (s + P)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,((s + P) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
SubFrom (GBP,2,SBP,(s + P)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,((s + P) + 1))) ';' (SubFrom (GBP,2,SBP,(s + P))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(GBP,2) := (SBP,(s + P)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(GBP,4) := (SBP,((s + P) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1)))) ';' () is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(s + P) + 3 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((s + P) + 3)) := (SBP,((s + P) + 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(SBP,((s + P) + 1)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
(s + P) + 2 is V1() epsilon-transitive epsilon-connected ordinal natural V11() V12() ext-real positive non negative integer V56() Element of NAT
(SBP,((s + P) + 2)) := (GBP,4) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
(((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((s + P) + 1),(- 1)) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((s + P) + 1),(- 1)*> is set
K75(8,0,<*SBP,((s + P) + 1),(- 1)*>) is set
((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
AddTo (SBP,((s + P) + 2),1) is V94( the InstructionsF of SCMPDS) shiftable parahalting Element of the InstructionsF of SCMPDS
<*SBP,((s + P) + 2),1*> is set
K75(8,0,<*SBP,((s + P) + 2),1*>) is set
(((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1))) ';' (AddTo (GBP,1,2)) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() halt-free V98( SCMPDS ) paraclosed parahalting shiftable V160() set
((((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1)))) ';' ()) ';' (((((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1))) ';' (AddTo (GBP,1,2))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
if>0 (GBP,2,(((((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1)))) ';' ()) ';' (((((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
(((GBP,2) := (SBP,((s + P) + 1))) ';' (SubFrom (GBP,2,SBP,(s + P)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1)))) ';' ()) ';' (((((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
while>0 (GBP,1,((((GBP,2) := (SBP,((s + P) + 1))) ';' (SubFrom (GBP,2,SBP,(s + P)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1)))) ';' ()) ';' (((((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2)))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
((((GBP := 0) ';' (SBP := 1)) ';' ((SBP,(s + P)) := (s + 1))) ';' ((SBP,((s + P) + 1)) := (s + P))) ';' (while>0 (GBP,1,((((GBP,2) := (SBP,((s + P) + 1))) ';' (SubFrom (GBP,2,SBP,(s + P)))) ';' (if>0 (GBP,2,(((((GBP,2) := (SBP,(s + P))) ';' ((GBP,4) := (SBP,((s + P) + 1)))) ';' ()) ';' (((((((SBP,((s + P) + 3)) := (SBP,((s + P) + 1))) ';' ((SBP,((s + P) + 1)) := (GBP,4))) ';' ((SBP,((s + P) + 2)) := (GBP,4))) ';' (AddTo (SBP,((s + P) + 1),(- 1)))) ';' (AddTo (SBP,((s + P) + 2),1))) ';' (AddTo (GBP,1,2)))),(Load (AddTo (GBP,1,(- 2))))))))) is V1() T-Sequence-like Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V45() V88() V160() set
p0 is V1() Relation-like NAT -defined the InstructionsF of SCMPDS -valued Function-like V23( NAT ) set
IExec ((P,s),p0,n) is Relation-like the U1 of SCMPDS -defined Function-like the_Values_of SCMPDS -compatible V23( the U1 of SCMPDS) set