subroutine prja (neq, y, yh, nyh, ewt, ftem, savf, wm, iwm, 1 f, jac) clll. optimize external f, jac integer neq, nyh, iwm integer iownd, iowns, 1 icf, ierpj, iersl, jcur, jstart, kflag, l, meth, miter, 2 maxord, maxcor, msbp, mxncf, n, nq, nst, nfe, nje, nqu integer iownd2, iowns2, jtyp, mused, mxordn, mxords integer i, i1, i2, ier, ii, j, j1, jj, lenp, 1 mba, mband, meb1, meband, ml, ml3, mu double precision y, yh, ewt, ftem, savf, wm double precision rownd, rowns, 1 ccmax, el0, h, hmin, hmxi, hu, rc, tn, uround double precision rownd2, rowns2, pdnorm double precision con, di, fac, hl0, r, r0, srur, yi, yj, yjj, 1 vmnorm, fnorm, bnorm dimension neq(1), y(1), yh(nyh,1), ewt(1), ftem(1), savf(1), 1 wm(1), iwm(1) common /ls0001/ rownd, rowns(209), 2 ccmax, el0, h, hmin, hmxi, hu, rc, tn, uround, 3 iownd(14), iowns(6), 4 icf, ierpj, iersl, jcur, jstart, kflag, l, meth, miter, 5 maxord, maxcor, msbp, mxncf, n, nq, nst, nfe, nje, nqu common /lsa001/ rownd2, rowns2(20), pdnorm, 1 iownd2(3), iowns2(2), jtyp, mused, mxordn, mxords c----------------------------------------------------------------------- c prja is called by stoda to compute and process the matrix c p = i - h*el(1)*j , where j is an approximation to the jacobian. c here j is computed by the user-supplied routine jac if c miter = 1 or 4 or by finite differencing if miter = 2 or 5. c j, scaled by -h*el(1), is stored in wm. then the norm of j (the c matrix norm consistent with the weighted max-norm on vectors given c by vmnorm) is computed, and j is overwritten by p. p is then c subjected to lu decomposition in preparation for later solution c of linear systems with p as coefficient matrix. this is done c by dgefa if miter = 1 or 2, and by dgbfa if miter = 4 or 5. c c in addition to variables described previously, communication c with prja uses the following.. c y = array containing predicted values on entry. c ftem = work array of length n (acor in stoda). c savf = array containing f evaluated at predicted y. c wm = real work space for matrices. on output it contains the c lu decomposition of p. c storage of matrix elements starts at wm(3). c wm also contains the following matrix-related data.. c wm(1) = sqrt(uround), used in numerical jacobian increments. c iwm = integer work space containing pivot information, starting at c iwm(21). iwm also contains the band parameters c ml = iwm(1) and mu = iwm(2) if miter is 4 or 5. c el0 = el(1) (input). c pdnorm= norm of jacobian matrix. (output). c ierpj = output error flag, = 0 if no trouble, .gt. 0 if c p matrix found to be singular. c jcur = output flag = 1 to indicate that the jacobian matrix c (or approximation) is now current. c this routine also uses the common variables el0, h, tn, uround, c miter, n, nfe, and nje. c----------------------------------------------------------------------- nje = nje + 1 ierpj = 0 jcur = 1 hl0 = h*el0 go to (100, 200, 300, 400, 500), miter c if miter = 1, call jac and multiply by scalar. ----------------------- 100 lenp = n*n do 110 i = 1,lenp 110 wm(i+2) = 0.0d0 call jac (neq, tn, y, 0, 0, wm(3), n) con = -hl0 do 120 i = 1,lenp 120 wm(i+2) = wm(i+2)*con go to 240 c if miter = 2, make n calls to f to approximate j. -------------------- 200 fac = vmnorm (n, savf, ewt) r0 = 1000.0d0*dabs(h)*uround*dfloat(n)*fac if (r0 .eq. 0.0d0) r0 = 1.0d0 srur = wm(1) j1 = 2 do 230 j = 1,n yj = y(j) r = dmax1(srur*dabs(yj),r0/ewt(j)) y(j) = y(j) + r fac = -hl0/r call f (neq, tn, y, ftem) do 220 i = 1,n 220 wm(i+j1) = (ftem(i) - savf(i))*fac y(j) = yj j1 = j1 + n 230 continue nfe = nfe + n 240 continue c compute norm of jacobian. -------------------------------------------- pdnorm = fnorm (n, wm(3), ewt)/dabs(hl0) c add identity matrix. ------------------------------------------------- j = 3 do 250 i = 1,n wm(j) = wm(j) + 1.0d0 250 j = j + (n + 1) c do lu decomposition on p. -------------------------------------------- call dgefa (wm(3), n, n, iwm(21), ier) if (ier .ne. 0) ierpj = 1 return c dummy block only, since miter is never 3 in this routine. ------------ 300 return c if miter = 4, call jac and multiply by scalar. ----------------------- 400 ml = iwm(1) mu = iwm(2) ml3 = ml + 3 mband = ml + mu + 1 meband = mband + ml lenp = meband*n do 410 i = 1,lenp 410 wm(i+2) = 0.0d0 call jac (neq, tn, y, ml, mu, wm(ml3), meband) con = -hl0 do 420 i = 1,lenp 420 wm(i+2) = wm(i+2)*con go to 570 c if miter = 5, make mband calls to f to approximate j. ---------------- 500 ml = iwm(1) mu = iwm(2) mband = ml + mu + 1 mba = min0(mband,n) meband = mband + ml meb1 = meband - 1 srur = wm(1) fac = vmnorm (n, savf, ewt) r0 = 1000.0d0*dabs(h)*uround*dfloat(n)*fac if (r0 .eq. 0.0d0) r0 = 1.0d0 do 560 j = 1,mba do 530 i = j,n,mband yi = y(i) r = dmax1(srur*dabs(yi),r0/ewt(i)) 530 y(i) = y(i) + r call f (neq, tn, y, ftem) do 550 jj = j,n,mband y(jj) = yh(jj,1) yjj = y(jj) r = dmax1(srur*dabs(yjj),r0/ewt(jj)) fac = -hl0/r i1 = max0(jj-mu,1) i2 = min0(jj+ml,n) ii = jj*meb1 - ml + 2 do 540 i = i1,i2 540 wm(ii+i) = (ftem(i) - savf(i))*fac 550 continue 560 continue nfe = nfe + mba 570 continue c compute norm of jacobian. -------------------------------------------- pdnorm = bnorm (n, wm(3), meband, ml, mu, ewt)/dabs(hl0) c add identity matrix. ------------------------------------------------- ii = mband + 2 do 580 i = 1,n wm(ii) = wm(ii) + 1.0d0 580 ii = ii + meband c do lu decomposition of p. -------------------------------------------- call dgbfa (wm(3), meband, n, ml, mu, iwm(21), ier) if (ier .ne. 0) ierpj = 1 return c----------------------- end of subroutine prja ------------------------ end