Old engine for Continuous Time Bayesian Networks. Superseded by reCTBN. 🐍
https://github.com/madlabunimib/PyCTBN
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241 lines
6.5 KiB
241 lines
6.5 KiB
4 years ago
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c banded5x5.f
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c
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c This Fortran library contains implementations of the
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c differential equation
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c dy/dt = A*y
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c where A is a 5x5 banded matrix (see below for the actual
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c values). These functions will be used to test
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c scipy.integrate.odeint.
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c
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c The idea is to solve the system two ways: pure Fortran, and
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c using odeint. The "pure Fortran" solver is implemented in
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c the subroutine banded5x5_solve below. It calls LSODA to
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c solve the system.
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c
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c To solve the same system using odeint, the functions in this
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c file are given a python wrapper using f2py. Then the code
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c in test_odeint_jac.py uses the wrapper to implement the
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c equation and Jacobian functions required by odeint. Because
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c those functions ultimately call the Fortran routines defined
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c in this file, the two method (pure Fortran and odeint) should
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c produce exactly the same results. (That's assuming floating
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c point calculations are deterministic, which can be an
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c incorrect assumption.) If we simply re-implemented the
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c equation and Jacobian functions using just python and numpy,
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c the floating point calculations would not be performed in
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c the same sequence as in the Fortran code, and we would obtain
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c different answers. The answer for either method would be
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c numerically "correct", but the errors would be different,
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c and the counts of function and Jacobian evaluations would
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c likely be different.
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c
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block data jacobian
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implicit none
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double precision bands
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dimension bands(4,5)
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common /jac/ bands
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c The data for a banded Jacobian stored in packed banded
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c format. The full Jacobian is
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c
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c -1, 0.25, 0, 0, 0
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c 0.25, -5, 0.25, 0, 0
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c 0.10, 0.25, -25, 0.25, 0
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c 0, 0.10, 0.25, -125, 0.25
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c 0, 0, 0.10, 0.25, -625
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c
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c The columns in the following layout of numbers are
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c the upper diagonal, main diagonal and two lower diagonals
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c (i.e. each row in the layout is a column of the packed
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c banded Jacobian). The values 0.00D0 are in the "don't
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c care" positions.
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data bands/
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+ 0.00D0, -1.0D0, 0.25D0, 0.10D0,
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+ 0.25D0, -5.0D0, 0.25D0, 0.10D0,
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+ 0.25D0, -25.0D0, 0.25D0, 0.10D0,
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+ 0.25D0, -125.0D0, 0.25D0, 0.00D0,
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+ 0.25D0, -625.0D0, 0.00D0, 0.00D0
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+ /
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end
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subroutine getbands(jac)
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double precision jac
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dimension jac(4, 5)
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cf2py intent(out) jac
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double precision bands
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dimension bands(4,5)
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common /jac/ bands
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integer i, j
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do 5 i = 1, 4
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do 5 j = 1, 5
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jac(i, j) = bands(i, j)
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5 continue
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return
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end
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c
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c Differential equations, right-hand-side
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c
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subroutine banded5x5(n, t, y, f)
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implicit none
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integer n
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double precision t, y, f
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dimension y(n), f(n)
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double precision bands
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dimension bands(4,5)
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common /jac/ bands
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f(1) = bands(2,1)*y(1) + bands(1,2)*y(2)
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f(2) = bands(3,1)*y(1) + bands(2,2)*y(2) + bands(1,3)*y(3)
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f(3) = bands(4,1)*y(1) + bands(3,2)*y(2) + bands(2,3)*y(3)
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+ + bands(1,4)*y(4)
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f(4) = bands(4,2)*y(2) + bands(3,3)*y(3) + bands(2,4)*y(4)
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+ + bands(1,5)*y(5)
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f(5) = bands(4,3)*y(3) + bands(3,4)*y(4) + bands(2,5)*y(5)
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return
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end
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c
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c Jacobian
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c
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c The subroutine assumes that the full Jacobian is to be computed.
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c ml and mu are ignored, and nrowpd is assumed to be n.
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c
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subroutine banded5x5_jac(n, t, y, ml, mu, jac, nrowpd)
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implicit none
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integer n, ml, mu, nrowpd
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double precision t, y, jac
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dimension y(n), jac(nrowpd, n)
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integer i, j
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double precision bands
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dimension bands(4,5)
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common /jac/ bands
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do 15 i = 1, 4
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do 15 j = 1, 5
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if ((i - j) .gt. 0) then
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jac(i - j, j) = bands(i, j)
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end if
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15 continue
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return
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end
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c
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c Banded Jacobian
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c
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c ml = 2, mu = 1
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c
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subroutine banded5x5_bjac(n, t, y, ml, mu, bjac, nrowpd)
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implicit none
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integer n, ml, mu, nrowpd
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double precision t, y, bjac
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dimension y(5), bjac(nrowpd, n)
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integer i, j
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double precision bands
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dimension bands(4,5)
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common /jac/ bands
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do 20 i = 1, 4
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do 20 j = 1, 5
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bjac(i, j) = bands(i, j)
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20 continue
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return
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end
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subroutine banded5x5_solve(y, nsteps, dt, jt, nst, nfe, nje)
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c jt is the Jacobian type:
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c jt = 1 Use the full Jacobian.
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c jt = 4 Use the banded Jacobian.
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c nst, nfe and nje are outputs:
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c nst: Total number of internal steps
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c nfe: Total number of function (i.e. right-hand-side)
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c evaluations
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c nje: Total number of Jacobian evaluations
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implicit none
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external banded5x5
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external banded5x5_jac
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external banded5x5_bjac
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external LSODA
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c Arguments...
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double precision y, dt
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integer nsteps, jt, nst, nfe, nje
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cf2py intent(inout) y
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cf2py intent(in) nsteps, dt, jt
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cf2py intent(out) nst, nfe, nje
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c Local variables...
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double precision atol, rtol, t, tout, rwork
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integer iwork
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dimension y(5), rwork(500), iwork(500)
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integer neq, i
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integer itol, iopt, itask, istate, lrw, liw
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c Common block...
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double precision jacband
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dimension jacband(4,5)
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common /jac/ jacband
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c --- t range ---
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t = 0.0D0
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c --- Solver tolerances ---
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rtol = 1.0D-11
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atol = 1.0D-13
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itol = 1
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c --- Other LSODA parameters ---
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neq = 5
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itask = 1
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istate = 1
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iopt = 0
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iwork(1) = 2
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iwork(2) = 1
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lrw = 500
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liw = 500
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c --- Call LSODA in a loop to compute the solution ---
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do 40 i = 1, nsteps
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tout = i*dt
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if (jt .eq. 1) then
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call LSODA(banded5x5, neq, y, t, tout,
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& itol, rtol, atol, itask, istate, iopt,
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& rwork, lrw, iwork, liw,
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& banded5x5_jac, jt)
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else
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call LSODA(banded5x5, neq, y, t, tout,
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& itol, rtol, atol, itask, istate, iopt,
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& rwork, lrw, iwork, liw,
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& banded5x5_bjac, jt)
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end if
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40 if (istate .lt. 0) goto 80
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nst = iwork(11)
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nfe = iwork(12)
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nje = iwork(13)
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return
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80 write (6,89) istate
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89 format(1X,"Error: istate=",I3)
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return
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end
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