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subroutine mux(flag,nevprt,t,xd,x,nx,z,nz,tvec,ntvec,
& rpar,nrpar,ipar,nipar,uy1,nuy1,uy2,nuy2,uy3,nuy3,uy4,
c Copyright INRIA
& nuy4,uy5,nuy5,uy6,nuy6,uy7,nuy7,uy8,nuy8,uy9,nuy9)
c Scicos block simulator
c ipar(1) : the number of input
c
double precision t,xd(*),x(*),z(*),tvec(*),rpar(*)
double precision uy1(*),uy2(*),uy3(*),uy4(*),uy5(*),uy6(*)
double precision uy7(*),uy8(*),uy9(*)
integer flag,nevprt,nx,nz,ntvec,nrpar,ipar(*)
integer nipar
integer k
c
common /dbcos/ idb
c
if(idb.eq.1) then
write(6,'(''mux t='',e10.3,'' flag='',i1)') t,flag
endif
c
k=0
goto(20,30,40,50,60,70,80),ipar(1)-1
c
20 do 25 i=1,nuy1
k=k+1
uy3(k)=uy1(i)
25 continue
do 27 i=1,nuy2
k=k+1
uy3(k)=uy2(i)
27 continue
return
c
30 do 35 i=1,nuy1
k=k+1
uy4(k)=uy1(i)
35 continue
do 37 i=1,nuy2
k=k+1
uy4(k)=uy2(i)
37 continue
do 38 i=1,nuy3
k=k+1
uy4(k)=uy3(i)
38 continue
return
c
40 do 41 i=1,nuy1
k=k+1
uy5(k)=uy1(i)
41 continue
do 42 i=1,nuy2
k=k+1
uy5(k)=uy2(i)
42 continue
do 43 i=1,nuy3
k=k+1
uy5(k)=uy3(i)
43 continue
do 44 i=1,nuy4
k=k+1
uy5(k)=uy4(i)
44 continue
return
c
50 do 51 i=1,nuy1
k=k+1
uy6(k)=uy1(i)
51 continue
do 52 i=1,nuy2
k=k+1
uy6(k)=uy2(i)
52 continue
do 53 i=1,nuy3
k=k+1
uy6(k)=uy3(i)
53 continue
do 54 i=1,nuy4
k=k+1
uy6(k)=uy4(i)
54 continue
do 55 i=1,nuy5
k=k+1
uy6(k)=uy5(i)
55 continue
return
c
60 do 61 i=1,nuy1
k=k+1
uy7(k)=uy1(i)
61 continue
do 62 i=1,nuy2
k=k+1
uy7(k)=uy2(i)
62 continue
do 63 i=1,nuy3
k=k+1
uy7(k)=uy3(i)
63 continue
do 64 i=1,nuy4
k=k+1
uy7(k)=uy4(i)
64 continue
do 65 i=1,nuy5
k=k+1
uy7(k)=uy5(i)
65 continue
do 66 i=1,nuy6
k=k+1
uy7(k)=uy6(i)
66 continue
return
c
70 do 71 i=1,nuy1
k=k+1
uy8(k)=uy1(i)
71 continue
do 72 i=1,nuy2
k=k+1
uy8(k)=uy2(i)
72 continue
do 73 i=1,nuy3
k=k+1
uy8(k)=uy3(i)
73 continue
do 74 i=1,nuy4
k=k+1
uy8(k)=uy4(i)
74 continue
do 75 i=1,nuy5
k=k+1
uy8(k)=uy5(i)
75 continue
do 76 i=1,nuy6
k=k+1
uy8(k)=uy6(i)
76 continue
do 77 i=1,nuy7
k=k+1
uy8(k)=uy7(i)
77 continue
return
c
80 do 81 i=1,nuy1
k=k+1
uy9(k)=uy1(i)
81 continue
do 82 i=1,nuy2
k=k+1
uy9(k)=uy2(i)
82 continue
do 83 i=1,nuy3
k=k+1
uy9(k)=uy3(i)
83 continue
do 84 i=1,nuy4
k=k+1
uy9(k)=uy4(i)
84 continue
do 85 i=1,nuy5
k=k+1
uy9(k)=uy5(i)
85 continue
do 86 i=1,nuy6
k=k+1
uy9(k)=uy6(i)
86 continue
do 87 i=1,nuy7
k=k+1
uy9(k)=uy7(i)
87 continue
do 88 i=1,nuy8
k=k+1
uy9(k)=uy8(i)
88 continue
return
end
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