C$TEST TTGU1P c main program c to solve the heat equation with solution u == t*x*y, c grad . ( u + ux + .1 * uy, u + uy + .1 * ux ) = ut + ux + uy +g(x,t) common /cstak/ ds real ds(350000) integer ixb(4), iyb(4), nxr(4), nyr(4), kxr(4), kyr(4) external handlu, bc, af integer ndx, ndy, istkgt, is(1000), iu, nu, kx, ky, IUMB real errpar(2), rs(1000) logical ls(1000) complex cs(500) real tstart, dt, tstop, ws(500) c the port library stack and its aliases. equivalence (ds(1), cs(1), ws(1), rs(1), is(1), ls(1)) c initialize the port library stack length. call istkin(350000, 3) call enter(1) nu = 1 kx = 2 ky = 2 ndx = 3 ndy = 3 nr=4 tstart = 0.e0 tstop = 1.e0 dt = 1 errpar(1) = 1e-2 errpar(2) = 1e-4 c uniform grid. c c make grid for t-shaped region c ixb(1) = IUMB(-1.0e0, 0.0e0, ndx, kx, nxr(1)) ixb(2) = IUMB(0.0e0, 1.0e0, ndx, kx, nxr(2)) ixb(3) = IUMB(1.0e0, 2.0e0, ndx, kx, nxr(3)) ixb(4) = IUMB(0.0e0, 1.0e0, ndx, kx, nxr(4)) iyb(1) = IUMB(0.0e0, 1.0e0, ndy, ky, nyr(1)) iyb(2) = IUMB(0.0e0, 1.0e0, ndy, ky, nyr(2)) iyb(3) = IUMB(0.0e0, 1.0e0, ndy, ky, nyr(3)) iyb(4) = IUMB(-1.0e0, 0.0e0, ndy, ky, nyr(4)) nnu =nu*((nxr(1)-kx)*(nyr(1)+nyr(3)-2*ky)+ 1 (nxr(2)-kx)*(nyr(2)-ky)+ 4 (nxr(4)-kx)*(nyr(4)-ky)) nr=4 c space for the solution. iu = istkgt(nnu, 3) do 1 i=1,nr kxr(i)=kx kyr(i)=ky 1 continue c initial conditions for u. call SETR(nnu, 0.e0,ws(iu)) call ttgu(ws(iu),nu,nr,kxr,ws,nxr,ixb,kyr,ws,nyr,iyb,tstart, 1 tstop, dt, af, bc, errpar, handlu) call leave call wrapup stop end subroutine af(t, x, nx, y, ny, nu, u, ut, ux, uy, uxt, uyt 1 , a, au, aut, aux, auy, auxt, auyt, f, fu, fut, fux, fuy, fuxt, 2 fuyt) integer nu, nx, ny real t, x(nx), y(ny), u(nx, ny, nu), ut(nx, ny, nu), 1 ux(nx, ny, nu) real uy(nx, ny, nu), uxt(nx, ny, nu), uyt(nx, ny, nu), 1 a(nx, ny, nu, 2), au(nx, ny, nu, nu, 2), aut(nx, ny, nu, nu, 2) real aux(nx, ny, nu, nu, 2), auy(nx, ny, nu, nu, 2), 1 auxt(nx, ny, nu, nu, 2), auyt(nx, ny, nu, nu, 2), f(nx, ny, nu) 2 , fu(nx, ny, nu, nu) real fut(nx, ny, nu, nu), fux(nx, ny, nu, nu), fuy(nx, 1 ny, nu, nu), fuxt(nx, ny, nu, nu), fuyt(nx, ny, nu, nu) integer i, p, q do 3 i = 1, nu do 2 q = 1, ny do 1 p = 1, nx a(p, q, i, 1) = ux(p, q, i)+.1*uy(p, q, i)+u(p, q, i) a(p, q, i, 2) = uy(p, q, i)+.1*ux(p, q, i)+u(p, q, i) aux(p, q, i, i, 1) = 1 auy(p, q, i, i, 2) = 1 auy(p, q, i, i, 1) = .1 aux(p, q, i, i, 2) = .1 au(p, q, i, i, 1) = 1 au(p, q, i, i, 2) = 1 f(p, q, i) = ut(p, q, i)+ux(p, q, i)+uy(p, q, i) fut(p, q, i, i) = 1 fux(p, q, i, i) = 1 fuy(p, q, i, i) = 1 f(p, q, i) = f(p, q, i)+.2*t-x(p)*y(q) 1 continue 2 continue 3 continue return end subroutine bc(t, x, nx, y, ny, lx, rx, ly, ry, u, ut, ux, 1 uy, uxt, uyt, nu, b, bu, but, bux, buy, buxt, buyt) integer nu, nx, ny real t, x(nx), y(ny), lx, rx, ly real ry, u(nx, ny, nu), ut(nx, ny, nu), ux(nx, ny, nu) 1 , uy(nx, ny, nu), uxt(nx, ny, nu) real uyt(nx, ny, nu), b(nx, ny, nu), bu(nx, ny, nu, 1 nu), but(nx, ny, nu, nu), bux(nx, ny, nu, nu), buy(nx, ny, nu 2 , nu) real buxt(nx, ny, nu, nu), buyt(nx, ny, nu, nu) integer i, j do 2 j = 1, ny do 1 i = 1, nx bu(i, j, 1, 1) = 1 b(i, j, 1) = u(i, j, 1)-t*x(i)*y(j) 1 continue 2 continue return end subroutine ewe(t, x, nx, y, ny, u, nu) integer nu, nx, ny real t, x(nx), y(ny), u(nx, ny, nu) integer i, j, p c the exact solution. do 3 p = 1, nu do 2 i = 1, nx do 1 j = 1, ny u(i, j, p) = t*x(i)*y(j) 1 continue 2 continue 3 continue return end subroutine handlu(t0, u0, t, u, nv, dt, tstop) integer nv real t0, u0(nv), t, u(nv), dt, tstop common /a7tgup/ errpar, nu, mxp, myp integer nu real errpar(2) common /a7tgum/ kxp,ix,nxp,kyp,iy,nyp,nxnyt,nr,iup integer kx, ix, nx, ky, iy, ny common /cstak/is integer is(1000) iwrite=i1mach(2) if (t0 .ne. t) goto 2 write (iwrite, 1) t 1 format (16h restart for t =, 1pe10.2) return c get and print the error. 2 continue write(iwrite, 3)t 3 format(6h at t=,1pe10.2) ius=1 do 5 inu = 1, nu iyr=iy ixr=ix do 4 ir=1,nr ir1=ir-1 nx=is(nxp+ir1) ny=is(nyp+ir1) kx=is(kxp+ir1) ky=is(kyp+ir1) call gerr(kx, ixr, nx, ky, iyr, ny, u(ius), inu, t, ir) ixr=ixr+nx iyr=iyr+ny ius=ius+(nx-kx)*(ny-ky) 4 continue 5 continue return end subroutine gerr(kx, ix, nx, ky, iy, ny, u, inu, t, ir) c to print the solution at each time-step integer kx, ix, nx, ky, iy, ny integer inu, ir real u(1), t common /cstak/ ds real ds(500) integer ifa, ita(2), ixa(2), nta(2), nxa(2), ILUMD integer ixs, iys, nxs, nys, istkgt, i integer ka(2), ma(2), is(1000), i1mach real rs(1000) logical ls(1000) complex cs(500) real ws(500) integer temp equivalence (ds(1), cs(1), ws(1), rs(1), is(1), ls(1)) c u(nx-kx,ny-ky). c the port library stack and its aliases. call enter(1) c x search grid. c find the solution at 2 * 2 points / mesh rectangle. ixs = ILUMD(ws(ix), nx, 2, nxs) c y search grid. iys = ILUMD(ws(iy), ny, 2, nys) c u search grid values. ka(1) = kx ka(2) = ky ita(1) = ix ita(2) = iy nta(1) = nx nta(2) = ny ixa(1) = ixs ixa(2) = iys nxa(1) = nxs nxa(2) = nys ma(1) = 0 ma(2) = 0 c get solution. c approximate solution values. ifa = istkgt(nxs*nys, 3) c evaluate them. call tsd1(2, ka, ws, ita, nta, u, ws, ixa, nxa, ma, ws(ifa)) temp = i1mach(2) write(temp,9001)ir,inu,(ws(i),i=iFA,IFa+nxs*nys-1) 9001 format(" for rect",i3," u(.,",i2,")=", 1((1p5e10.2/20x,1p4d10.2))) call leave return end