*DECK SBCG SUBROUTINE SBCG (N, B, X, NELT, IA, JA, A, ISYM, MATVEC, MTTVEC, + MSOLVE, MTSOLV, ITOL, TOL, ITMAX, ITER, ERR, IERR, IUNIT, R, Z, + P, RR, ZZ, PP, DZ, RWORK, IWORK) C***BEGIN PROLOGUE SBCG C***PURPOSE Preconditioned BiConjugate Gradient Sparse Ax = b Solver. C Routine to solve a Non-Symmetric linear system Ax = b C using the Preconditioned BiConjugate Gradient method. C***LIBRARY SLATEC (SLAP) C***CATEGORY D2A4, D2B4 C***TYPE SINGLE PRECISION (SBCG-S, DBCG-D) C***KEYWORDS BICONJUGATE GRADIENT, ITERATIVE PRECONDITION, C NON-SYMMETRIC LINEAR SYSTEM, SLAP, SPARSE C***AUTHOR Greenbaum, Anne, (Courant Institute) C Seager, Mark K., (LLNL) C Lawrence Livermore National Laboratory C PO BOX 808, L-60 C Livermore, CA 94550 (510) 423-3141 C seager@llnl.gov C***DESCRIPTION C C *Usage: C INTEGER N, NELT, IA(NELT), JA(NELT), ISYM, ITOL, ITMAX C INTEGER ITER, IERR, IUNIT, IWORK(USER DEFINED) C REAL B(N), X(N), A(NELT), TOL, ERR, R(N), Z(N), P(N) C REAL RR(N), ZZ(N), PP(N), DZ(N) C REAL RWORK(USER DEFINED) C EXTERNAL MATVEC, MTTVEC, MSOLVE, MTSOLV C C CALL SBCG(N, B, X, NELT, IA, JA, A, ISYM, MATVEC, MTTVEC, C $ MSOLVE, MTSOLV, ITOL, TOL, ITMAX, ITER, ERR, IERR, IUNIT, C $ R, Z, P, RR, ZZ, PP, DZ, RWORK, IWORK) C C *Arguments: C N :IN Integer C Order of the Matrix. C B :IN Real B(N). C Right-hand side vector. C X :INOUT Real X(N). C On input X is your initial guess for solution vector. C On output X is the final approximate solution. C NELT :IN Integer. C Number of Non-Zeros stored in A. C IA :IN Integer IA(NELT). C JA :IN Integer JA(NELT). C A :IN Real A(NELT). C These arrays contain the matrix data structure for A. C It could take any form. See "Description", below, for more C details. C ISYM :IN Integer. C Flag to indicate symmetric storage format. C If ISYM=0, all non-zero entries of the matrix are stored. C If ISYM=1, the matrix is symmetric, and only the upper C or lower triangle of the matrix is stored. C MATVEC :EXT External. C Name of a routine which performs the matrix vector multiply C operation Y = A*X given A and X. The name of the MATVEC C routine must be declared external in the calling program. C The calling sequence of MATVEC is: C CALL MATVEC( N, X, Y, NELT, IA, JA, A, ISYM ) C Where N is the number of unknowns, Y is the product A*X upon C return, X is an input vector. NELT, IA, JA, A and ISYM C define the SLAP matrix data structure: see Description,below. C MTTVEC :EXT External. C Name of a routine which performs the matrix transpose vector C multiply y = A'*X given A and X (where ' denotes transpose). C The name of the MTTVEC routine must be declared external in C the calling program. The calling sequence to MTTVEC is the C same as that for MTTVEC, viz.: C CALL MTTVEC( N, X, Y, NELT, IA, JA, A, ISYM ) C Where N is the number of unknowns, Y is the product A'*X C upon return, X is an input vector. NELT, IA, JA, A and ISYM C define the SLAP matrix data structure: see Description,below. C MSOLVE :EXT External. C Name of a routine which solves a linear system MZ = R for Z C given R with the preconditioning matrix M (M is supplied via C RWORK and IWORK arrays). The name of the MSOLVE routine C must be declared external in the calling program. The C calling sequence of MSOLVE is: C CALL MSOLVE(N, R, Z, NELT, IA, JA, A, ISYM, RWORK, IWORK) C Where N is the number of unknowns, R is the right-hand side C vector, and Z is the solution upon return. NELT, IA, JA, A C and ISYM define the SLAP matrix data structure: see C Description, below. RWORK is a real array that can be used C to pass necessary preconditioning information and/or C workspace to MSOLVE. IWORK is an integer work array for the C same purpose as RWORK. C MTSOLV :EXT External. C Name of a routine which solves a linear system M'ZZ = RR for C ZZ given RR with the preconditioning matrix M (M is supplied C via RWORK and IWORK arrays). The name of the MTSOLV routine C must be declared external in the calling program. The call- C ing sequence to MTSOLV is: C CALL MTSOLV(N, RR, ZZ, NELT, IA, JA, A, ISYM, RWORK, IWORK) C Where N is the number of unknowns, RR is the right-hand side C vector, and ZZ is the solution upon return. NELT, IA, JA, A C and ISYM define the SLAP matrix data structure: see C Description, below. RWORK is a real array that can be used C to pass necessary preconditioning information and/or C workspace to MTSOLV. IWORK is an integer work array for the C same purpose as RWORK. C ITOL :IN Integer. C Flag to indicate type of convergence criterion. C If ITOL=1, iteration stops when the 2-norm of the residual C divided by the 2-norm of the right-hand side is less than TOL. C If ITOL=2, iteration stops when the 2-norm of M-inv times the C residual divided by the 2-norm of M-inv times the right hand C side is less than TOL, where M-inv is the inverse of the C diagonal of A. C ITOL=11 is often useful for checking and comparing different C routines. For this case, the user must supply the "exact" C solution or a very accurate approximation (one with an error C much less than TOL) through a common block, C COMMON /SSLBLK/ SOLN( ) C If ITOL=11, iteration stops when the 2-norm of the difference C between the iterative approximation and the user-supplied C solution divided by the 2-norm of the user-supplied solution C is less than TOL. Note that this requires the user to set up C the "COMMON /SSLBLK/ SOLN(LENGTH)" in the calling routine. C The routine with this declaration should be loaded before the C stop test so that the correct length is used by the loader. C This procedure is not standard Fortran and may not work C correctly on your system (although it has worked on every C system the authors have tried). If ITOL is not 11 then this C common block is indeed standard Fortran. C TOL :INOUT Real. C Convergence criterion, as described above. (Reset if IERR=4.) C ITMAX :IN Integer. C Maximum number of iterations. C ITER :OUT Integer. C Number of iterations required to reach convergence, or C ITMAX+1 if convergence criterion could not be achieved in C ITMAX iterations. C ERR :OUT Real. C Error estimate of error in final approximate solution, as C defined by ITOL. C IERR :OUT Integer. C Return error flag. C IERR = 0 => All went well. C IERR = 1 => Insufficient space allocated for WORK or IWORK. C IERR = 2 => Method failed to converge in ITMAX steps. C IERR = 3 => Error in user input. C Check input values of N, ITOL. C IERR = 4 => User error tolerance set too tight. C Reset to 500*R1MACH(3). Iteration proceeded. C IERR = 5 => Preconditioning matrix, M, is not positive C definite. (r,z) < 0. C IERR = 6 => Matrix A is not positive definite. (p,Ap) < 0. C IUNIT :IN Integer. C Unit number on which to write the error at each iteration, C if this is desired for monitoring convergence. If unit C number is 0, no writing will occur. C R :WORK Real R(N). C Z :WORK Real Z(N). C P :WORK Real P(N). C RR :WORK Real RR(N). C ZZ :WORK Real ZZ(N). C PP :WORK Real PP(N). C DZ :WORK Real DZ(N). C Real arrays used for workspace. C RWORK :WORK Real RWORK(USER DEFINED). C Real array that can be used for workspace in MSOLVE C and MTSOLV. C IWORK :WORK Integer IWORK(USER DEFINED). C Integer array that can be used for workspace in MSOLVE C and MTSOLV. C C *Description C This routine does not care what matrix data structure is used C for A and M. It simply calls MATVEC, MTTVEC, MSOLVE, MTSOLV C routines, with arguments as above. The user could write any C type of structure, and appropriate MATVEC, MSOLVE, MTTVEC, C and MTSOLV routines. It is assumed that A is stored in the C IA, JA, A arrays in some fashion and that M (or INV(M)) is C stored in IWORK and RWORK in some fashion. The SLAP C routines SSDBCG and SSLUBC are examples of this procedure. C C Two examples of matrix data structures are the: 1) SLAP C Triad format and 2) SLAP Column format. C C =================== S L A P Triad format =================== C In this format only the non-zeros are stored. They may C appear in *ANY* order. The user supplies three arrays of C length NELT, where NELT is the number of non-zeros in the C matrix: (IA(NELT), JA(NELT), A(NELT)). For each non-zero C the user puts the row and column index of that matrix C element in the IA and JA arrays. The value of the non-zero C matrix element is placed in the corresponding location of C the A array. This is an extremely easy data structure to C generate. On the other hand it is not too efficient on C vector computers for the iterative solution of linear C systems. Hence, SLAP changes this input data structure to C the SLAP Column format for the iteration (but does not C change it back). C C Here is an example of the SLAP Triad storage format for a C 5x5 Matrix. Recall that the entries may appear in any order. C C 5x5 Matrix SLAP Triad format for 5x5 matrix on left. C 1 2 3 4 5 6 7 8 9 10 11 C |11 12 0 0 15| A: 51 12 11 33 15 53 55 22 35 44 21 C |21 22 0 0 0| IA: 5 1 1 3 1 5 5 2 3 4 2 C | 0 0 33 0 35| JA: 1 2 1 3 5 3 5 2 5 4 1 C | 0 0 0 44 0| C |51 0 53 0 55| C C =================== S L A P Column format ================== C C In this format the non-zeros are stored counting down C columns (except for the diagonal entry, which must appear C first in each "column") and are stored in the real array A. C In other words, for each column in the matrix put the C diagonal entry in A. Then put in the other non-zero C elements going down the column (except the diagonal) in C order. The IA array holds the row index for each non-zero. C The JA array holds the offsets into the IA, A arrays for the C beginning of each column. That is, IA(JA(ICOL)), C A(JA(ICOL)) points to the beginning of the ICOL-th column in C IA and A. IA(JA(ICOL+1)-1), A(JA(ICOL+1)-1) points to the C end of the ICOL-th column. Note that we always have JA(N+1) C = NELT+1, where N is the number of columns in the matrix and C NELT is the number of non-zeros in the matrix. C C Here is an example of the SLAP Column storage format for a C 5x5 Matrix (in the A and IA arrays '|' denotes the end of a C column): C C 5x5 Matrix SLAP Column format for 5x5 matrix on left. C 1 2 3 4 5 6 7 8 9 10 11 C |11 12 0 0 15| A: 11 21 51 | 22 12 | 33 53 | 44 | 55 15 35 C |21 22 0 0 0| IA: 1 2 5 | 2 1 | 3 5 | 4 | 5 1 3 C | 0 0 33 0 35| JA: 1 4 6 8 9 12 C | 0 0 0 44 0| C |51 0 53 0 55| C C *Cautions: C This routine will attempt to write to the Fortran logical output C unit IUNIT, if IUNIT .ne. 0. Thus, the user must make sure that C this logical unit is attached to a file or terminal before calling C this routine with a non-zero value for IUNIT. This routine does C not check for the validity of a non-zero IUNIT unit number. C C***SEE ALSO SSDBCG, SSLUBC C***REFERENCES 1. Mark K. Seager, A SLAP for the Masses, in C G. F. Carey, Ed., Parallel Supercomputing: Methods, C Algorithms and Applications, Wiley, 1989, pp.135-155. C***ROUTINES CALLED ISSBCG, R1MACH, SAXPY, SCOPY, SDOT C***REVISION HISTORY (YYMMDD) C 871119 DATE WRITTEN C 881213 Previous REVISION DATE C 890915 Made changes requested at July 1989 CML Meeting. (MKS) C 890921 Removed TeX from comments. (FNF) C 890922 Numerous changes to prologue to make closer to SLATEC C standard. (FNF) C 890929 Numerous changes to reduce SP/DP differences. (FNF) C 891004 Added new reference. C 910411 Prologue converted to Version 4.0 format. (BAB) C 910502 Removed MATVEC, MTTVEC, MSOLVE, MTSOLV from ROUTINES C CALLED list. (FNF) C 920407 COMMON BLOCK renamed SSLBLK. (WRB) C 920511 Added complete declaration section. (WRB) C 920929 Corrected format of reference. (FNF) C 921019 Changed 500.0 to 500 to reduce SP/DP differences. (FNF) C 921113 Corrected C***CATEGORY line. (FNF) C***END PROLOGUE SBCG C .. Scalar Arguments .. REAL ERR, TOL INTEGER IERR, ISYM, ITER, ITMAX, ITOL, IUNIT, N, NELT C .. Array Arguments .. REAL A(NELT), B(N), DZ(N), P(N), PP(N), R(N), RR(N), RWORK(*), + X(N), Z(N), ZZ(N) INTEGER IA(NELT), IWORK(*), JA(NELT) C .. Subroutine Arguments .. EXTERNAL MATVEC, MSOLVE, MTSOLV, MTTVEC C .. Local Scalars .. REAL AK, AKDEN, BK, BKDEN, BKNUM, BNRM, FUZZ, SOLNRM, TOLMIN INTEGER I, K C .. External Functions .. REAL R1MACH, SDOT INTEGER ISSBCG EXTERNAL R1MACH, SDOT, ISSBCG C .. External Subroutines .. EXTERNAL SAXPY, SCOPY C .. Intrinsic Functions .. INTRINSIC ABS C***FIRST EXECUTABLE STATEMENT SBCG C C Check some of the input data. C ITER = 0 IERR = 0 IF( N.LT.1 ) THEN IERR = 3 RETURN ENDIF FUZZ = R1MACH(3) TOLMIN = 500*FUZZ FUZZ = FUZZ*FUZZ IF( TOL.LT.TOLMIN ) THEN TOL = TOLMIN IERR = 4 ENDIF C C Calculate initial residual and pseudo-residual, and check C stopping criterion. CALL MATVEC(N, X, R, NELT, IA, JA, A, ISYM) DO 10 I = 1, N R(I) = B(I) - R(I) RR(I) = R(I) 10 CONTINUE CALL MSOLVE(N, R, Z, NELT, IA, JA, A, ISYM, RWORK, IWORK) CALL MTSOLV(N, RR, ZZ, NELT, IA, JA, A, ISYM, RWORK, IWORK) C IF( ISSBCG(N, B, X, NELT, IA, JA, A, ISYM, MSOLVE, ITOL, TOL, $ ITMAX, ITER, ERR, IERR, IUNIT, R, Z, P, RR, ZZ, PP, $ DZ, RWORK, IWORK, AK, BK, BNRM, SOLNRM) .NE. 0 ) $ GO TO 200 IF( IERR.NE.0 ) RETURN C C ***** iteration loop ***** C DO 100 K=1,ITMAX ITER = K C C Calculate coefficient BK and direction vectors P and PP. BKNUM = SDOT(N, Z, 1, RR, 1) IF( ABS(BKNUM).LE.FUZZ ) THEN IERR = 6 RETURN ENDIF IF(ITER .EQ. 1) THEN CALL SCOPY(N, Z, 1, P, 1) CALL SCOPY(N, ZZ, 1, PP, 1) ELSE BK = BKNUM/BKDEN DO 20 I = 1, N P(I) = Z(I) + BK*P(I) PP(I) = ZZ(I) + BK*PP(I) 20 CONTINUE ENDIF BKDEN = BKNUM C C Calculate coefficient AK, new iterate X, new residuals R and C RR, and new pseudo-residuals Z and ZZ. CALL MATVEC(N, P, Z, NELT, IA, JA, A, ISYM) AKDEN = SDOT(N, PP, 1, Z, 1) AK = BKNUM/AKDEN IF( ABS(AKDEN).LE.FUZZ ) THEN IERR = 6 RETURN ENDIF CALL SAXPY(N, AK, P, 1, X, 1) CALL SAXPY(N, -AK, Z, 1, R, 1) CALL MTTVEC(N, PP, ZZ, NELT, IA, JA, A, ISYM) CALL SAXPY(N, -AK, ZZ, 1, RR, 1) CALL MSOLVE(N, R, Z, NELT, IA, JA, A, ISYM, RWORK, IWORK) CALL MTSOLV(N, RR, ZZ, NELT, IA, JA, A, ISYM, RWORK, IWORK) C C check stopping criterion. IF( ISSBCG(N, B, X, NELT, IA, JA, A, ISYM, MSOLVE, ITOL, TOL, $ ITMAX, ITER, ERR, IERR, IUNIT, R, Z, P, RR, ZZ, $ PP, DZ, RWORK, IWORK, AK, BK, BNRM, SOLNRM) .NE. 0 ) $ GO TO 200 C 100 CONTINUE C C ***** end of loop ***** C C stopping criterion not satisfied. ITER = ITMAX + 1 IERR = 2 C 200 RETURN C------------- LAST LINE OF SBCG FOLLOWS ---------------------------- END