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view liboctave/UMFPACK/UMFPACK/Demo/umf4zhb.f @ 5164:57077d0ddc8e
[project @ 2005-02-25 19:55:24 by jwe]
| author | jwe |
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| date | Fri, 25 Feb 2005 19:55:28 +0000 |
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c======================================================================= c== umf4zhb ============================================================ c======================================================================= c----------------------------------------------------------------------- c UMFPACK Version 4.4, Copyright (c) 2005 by Timothy A. Davis. CISE c Dept, Univ. of Florida. All Rights Reserved. See ../Doc/License for c License. web: http://www.cise.ufl.edu/research/sparse/umfpack c----------------------------------------------------------------------- c umf4zhb: c read a sparse matrix in the Harwell/Boeing format, factorizes c it, and solves Ax=b. Also saves and loads the factors to/from a c file. Saving to a file is not required, it's just here to c demonstrate how to use this feature of UMFPACK. This program c only works on square CUA-type matrices. c c This is HIGHLY non-portable. It may not work with your C and c FORTRAN compilers. See umf4z_f77wrapper.c for more details. c c usage (for example): c c in a Unix shell: c umf4zhb < HB/arc130.cua integer $ nzmax, nmax parameter (nzmax = 5000000, nmax = 160000) integer $ Ap (nmax), Ai (nzmax), n, nz, totcrd, ptrcrd, i, j, p, $ indcrd, valcrd, rhscrd, ncol, nrow, nrhs, nzrhs, nel, $ numeric, symbolic, status, sys, filenum character title*72, key*30, type*3, ptrfmt*16, $ indfmt*16, valfmt*20, rhsfmt*20 double precision Ax (nzmax), x (nmax), b (nmax), $ control (20), info (90) complex*16 AA (nzmax), XX (nmax), BB (nmax), r (nmax), aij, xj double precision Az (nmax), xz (nmax), bz (nmax), xi, xr character rhstyp*3 c ---------------------------------------------------------------- c read the Harwell/Boeing matrix c ---------------------------------------------------------------- read (5, 10, err = 998) $ title, key, $ totcrd, ptrcrd, indcrd, valcrd, rhscrd, $ type, nrow, ncol, nz, nel, $ ptrfmt, indfmt, valfmt, rhsfmt if (rhscrd .gt. 0) then c new Harwell/Boeing format: read (5, 20, err = 998) rhstyp, nrhs, nzrhs endif 10 format (a72, a8 / 5i14 / a3, 11x, 4i14 / 2a16, 2a20) 20 format (a3, 11x, 2i14) print *, 'Matrix key: ', key n = nrow if (type .ne. 'CUA' .or. nrow .ne. ncol) then print *, 'Error: can only handle square CUA matrices' stop endif if (n .ge. nmax .or. nz .gt. nzmax) then print *, ' Matrix too big!' stop endif c read the matrix (1-based) read (5, ptrfmt, err = 998) (Ap (p), p = 1, ncol+1) read (5, indfmt, err = 998) (Ai (p), p = 1, nz) read (5, valfmt, err = 998) (AA (p), p = 1, nz) do 15 p = 1, nz Ax (p) = dble (AA (p)) Az (p) = imag (AA (p)) 15 continue c ---------------------------------------------------------------- c create the right-hand-side, assume c x (i) = (1 + i/n), (n + i/100) c ---------------------------------------------------------------- do 30 i = 1,n BB (i) = 0 30 continue c b = A*x do 50 j = 1,n xr = j xi = n xi = xi + xr/100 xr = 1 + xr / n xj = dcmplx (xr, xi) do 40 p = Ap (j), Ap (j+1)-1 i = Ai (p) aij = AA (p) BB (i) = BB (i) + aij * xj 40 continue 50 continue do 32 i = 1,n b (i) = dble (BB (i)) bz (i) = imag (BB (i)) 32 continue c ---------------------------------------------------------------- c convert from 1-based to 0-based c ---------------------------------------------------------------- do 60 j = 1, n+1 Ap (j) = Ap (j) - 1 60 continue do 70 p = 1, nz Ai (p) = Ai (p) - 1 70 continue c ---------------------------------------------------------------- c factor the matrix and save to a file c ---------------------------------------------------------------- c set default parameters call umf4zdef (control) c print control parameters. set control (1) to 1 to print c error messages only control (1) = 2 call umf4zpcon (control) c pre-order and symbolic analysis call umf4zsym (n, n, Ap, Ai, Ax, Az, symbolic, control, info) c print statistics computed so far c call umf4zpinf (control, info) could also be done. print 80, info (1), info (16), $ (info (21) * info (4)) / 2**20, $ (info (22) * info (4)) / 2**20, $ info (23), info (24), info (25) 80 format ('symbolic analysis:',/, $ ' status: ', f5.0, /, $ ' time: ', e10.2, ' (sec)'/, $ ' estimates (upper bound) for numeric LU:', /, $ ' size of LU: ', f10.2, ' (MB)', /, $ ' memory needed: ', f10.2, ' (MB)', /, $ ' flop count: ', e10.2, / $ ' nnz (L): ', f10.0, / $ ' nnz (U): ', f10.0) c check umf4zsym error condition if (info (1) .lt. 0) then print *, 'Error occurred in umf4zsym: ', info (1) stop endif c numeric factorization call umf4znum (Ap, Ai, Ax, Az, symbolic, numeric, control, info) c print statistics for the numeric factorization c call umf4zpinf (control, info) could also be done. print 90, info (1), info (66), $ (info (41) * info (4)) / 2**20, $ (info (42) * info (4)) / 2**20, $ info (43), info (44), info (45) 90 format ('numeric factorization:',/, $ ' status: ', f5.0, /, $ ' time: ', e10.2, /, $ ' actual numeric LU statistics:', /, $ ' size of LU: ', f10.2, ' (MB)', /, $ ' memory needed: ', f10.2, ' (MB)', /, $ ' flop count: ', e10.2, / $ ' nnz (L): ', f10.0, / $ ' nnz (U): ', f10.0) c check umf4znum error condition if (info (1) .lt. 0) then print *, 'Error occurred in umf4znum: ', info (1) stop endif c save the symbolic analysis to the file s42.umf c note that this is not needed until another matrix is c factorized, below. filenum = 42 call umf4zssym (symbolic, filenum, status) if (status .lt. 0) then print *, 'Error occurred in umf4zssym: ', status stop endif c save the LU factors to the file n0.umf call umf4zsnum (numeric, filenum, status) if (status .lt. 0) then print *, 'Error occurred in umf4zsnum: ', status stop endif c free the symbolic analysis call umf4zfsym (symbolic) c free the numeric factorization call umf4zfnum (numeric) c No LU factors (symbolic or numeric) are in memory at this point. c ---------------------------------------------------------------- c load the LU factors back in, and solve the system c ---------------------------------------------------------------- c At this point the program could terminate and load the LU C factors (numeric) from the n0.umf file, and solve the c system (see below). Note that the symbolic object is not c required. c load the numeric factorization back in (filename: n0.umf) call umf4zlnum (numeric, filenum, status) if (status .lt. 0) then print *, 'Error occurred in umf4zlnum: ', status stop endif c solve Ax=b, without iterative refinement sys = 0 call umf4zsol (sys, x, xz, b, bz, numeric, control, info) if (info (1) .lt. 0) then print *, 'Error occurred in umf4zsol: ', info (1) stop endif do 33 i = 1,n XX (i) = dcmplx (x (i), xz (i)) 33 continue c free the numeric factorization call umf4zfnum (numeric) c No LU factors (symbolic or numeric) are in memory at this point. c print final statistics call umf4zpinf (control, info) c print the residual. x (i) should be 1 + i/n call resid (n, nz, Ap, Ai, AA, XX, BB, r) stop 998 print *, 'Read error: Harwell/Boeing matrix' stop end c======================================================================= c== resid ============================================================== c======================================================================= c Compute the residual, r = Ax-b, its max-norm, and print the max-norm C Note that A is zero-based. subroutine resid (n, nz, Ap, Ai, A, x, b, r) integer $ n, nz, Ap (n+1), Ai (n), j, i, p complex*16 A (nz), x (n), b (n), r (n), aij double precision rmax do 10 i = 1, n r (i) = -b (i) 10 continue do 30 j = 1,n do 20 p = Ap (j) + 1, Ap (j+1) i = Ai (p) + 1 aij = A (p) r (i) = r (i) + aij * x (j) 20 continue 30 continue rmax = 0 do 40 i = 1, n rmax = max (rmax, abs (r (i))) 40 continue print *, 'norm (A*x-b): ', rmax return end