219 lines
6.0 KiB
Fortran
219 lines
6.0 KiB
Fortran
c
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c L-BFGS-B is released under the “New BSD License” (aka “Modified BSD License”
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c or “3-clause license”)
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c Please read attached file License.txt
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c
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subroutine dpofa(a,lda,n,info)
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integer lda,n,info
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double precision a(lda,*)
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c
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c dpofa factors a double precision symmetric positive definite
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c matrix.
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c
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c dpofa is usually called by dpoco, but it can be called
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c directly with a saving in time if rcond is not needed.
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c (time for dpoco) = (1 + 18/n)*(time for dpofa) .
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c
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c on entry
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c
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c a double precision(lda, n)
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c the symmetric matrix to be factored. only the
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c diagonal and upper triangle are used.
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c
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c lda integer
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c the leading dimension of the array a .
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c
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c n integer
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c the order of the matrix a .
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c
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c on return
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c
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c a an upper triangular matrix r so that a = trans(r)*r
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c where trans(r) is the transpose.
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c the strict lower triangle is unaltered.
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c if info .ne. 0 , the factorization is not complete.
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c
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c info integer
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c = 0 for normal return.
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c = k signals an error condition. the leading minor
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c of order k is not positive definite.
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c
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c linpack. this version dated 08/14/78 .
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c cleve moler, university of new mexico, argonne national lab.
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c
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c subroutines and functions
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c
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c blas ddot
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c fortran sqrt
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c
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c internal variables
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c
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double precision ddot,t
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double precision s
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integer j,jm1,k
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c begin block with ...exits to 40
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c
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c
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do 30 j = 1, n
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info = j
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s = 0.0d0
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jm1 = j - 1
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if (jm1 .lt. 1) go to 20
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do 10 k = 1, jm1
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t = a(k,j) - ddot(k-1,a(1,k),1,a(1,j),1)
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t = t/a(k,k)
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a(k,j) = t
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s = s + t*t
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10 continue
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20 continue
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s = a(j,j) - s
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c ......exit
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if (s .le. 0.0d0) go to 40
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a(j,j) = sqrt(s)
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30 continue
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info = 0
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40 continue
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return
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end
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c====================== The end of dpofa ===============================
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subroutine dtrsl(t,ldt,n,b,job,info)
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integer ldt,n,job,info
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double precision t(ldt,*),b(*)
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c
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c
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c dtrsl solves systems of the form
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c
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c t * x = b
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c or
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c trans(t) * x = b
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c
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c where t is a triangular matrix of order n. here trans(t)
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c denotes the transpose of the matrix t.
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c
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c on entry
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c
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c t double precision(ldt,n)
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c t contains the matrix of the system. the zero
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c elements of the matrix are not referenced, and
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c the corresponding elements of the array can be
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c used to store other information.
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c
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c ldt integer
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c ldt is the leading dimension of the array t.
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c
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c n integer
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c n is the order of the system.
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c
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c b double precision(n).
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c b contains the right hand side of the system.
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c
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c job integer
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c job specifies what kind of system is to be solved.
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c if job is
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c
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c 00 solve t*x=b, t lower triangular,
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c 01 solve t*x=b, t upper triangular,
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c 10 solve trans(t)*x=b, t lower triangular,
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c 11 solve trans(t)*x=b, t upper triangular.
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c
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c on return
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c
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c b b contains the solution, if info .eq. 0.
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c otherwise b is unaltered.
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c
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c info integer
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c info contains zero if the system is nonsingular.
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c otherwise info contains the index of
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c the first zero diagonal element of t.
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c
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c linpack. this version dated 08/14/78 .
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c g. w. stewart, university of maryland, argonne national lab.
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c
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c subroutines and functions
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c
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c blas daxpy,ddot
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c fortran mod
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c
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c internal variables
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c
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double precision ddot,temp
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integer case,j,jj
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c
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c begin block permitting ...exits to 150
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c
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c check for zero diagonal elements.
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c
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do 10 info = 1, n
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c ......exit
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if (t(info,info) .eq. 0.0d0) go to 150
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10 continue
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info = 0
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c
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c determine the task and go to it.
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c
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case = 1
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if (mod(job,10) .ne. 0) case = 2
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if (mod(job,100)/10 .ne. 0) case = case + 2
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go to (20,50,80,110), case
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c
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c solve t*x=b for t lower triangular
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c
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20 continue
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b(1) = b(1)/t(1,1)
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if (n .lt. 2) go to 40
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do 30 j = 2, n
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temp = -b(j-1)
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call daxpy(n-j+1,temp,t(j,j-1),1,b(j),1)
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b(j) = b(j)/t(j,j)
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30 continue
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40 continue
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go to 140
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c
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c solve t*x=b for t upper triangular.
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c
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50 continue
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b(n) = b(n)/t(n,n)
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if (n .lt. 2) go to 70
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do 60 jj = 2, n
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j = n - jj + 1
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temp = -b(j+1)
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call daxpy(j,temp,t(1,j+1),1,b(1),1)
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b(j) = b(j)/t(j,j)
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60 continue
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70 continue
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go to 140
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c
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c solve trans(t)*x=b for t lower triangular.
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c
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80 continue
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b(n) = b(n)/t(n,n)
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if (n .lt. 2) go to 100
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do 90 jj = 2, n
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j = n - jj + 1
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b(j) = b(j) - ddot(jj-1,t(j+1,j),1,b(j+1),1)
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b(j) = b(j)/t(j,j)
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90 continue
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100 continue
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go to 140
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c
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c solve trans(t)*x=b for t upper triangular.
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c
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110 continue
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b(1) = b(1)/t(1,1)
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if (n .lt. 2) go to 130
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do 120 j = 2, n
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b(j) = b(j) - ddot(j-1,t(1,j),1,b(1),1)
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b(j) = b(j)/t(j,j)
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120 continue
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130 continue
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140 continue
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150 continue
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return
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end
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c====================== The end of dtrsl ===============================
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