/* ------------------------- basic initializion method created -- 98jan22, cca ------------------------- */ void ZV_init1 ( ZV *zv, int size ) { ZV_init(zv, size, NULL) ; return ; }
/*--------------------------------------------------------------------*/ int main ( int argc, char *argv[] ) /* ------------------------------------------ test the SubMtx_scale{1,2,3}vec() methods. created -- 98may02, cca ------------------------------------------ */ { SubMtx *mtxA ; double t1, t2 ; double *x0, *x1, *x2, *y0, *y1, *y2 ; Drand *drand ; DV *xdv0, *xdv1, *xdv2, *ydv0, *ydv1, *ydv2 ; ZV *xzv0, *xzv1, *xzv2, *yzv0, *yzv1, *yzv2 ; FILE *msgFile ; int mode, msglvl, nrowA, seed, type ; if ( argc != 7 ) { fprintf(stdout, "\n\n usage : %s msglvl msgFile type nrowA seed" "\n msglvl -- message level" "\n msgFile -- message file" "\n type -- type of matrix A" "\n 1 -- real" "\n 2 -- complex" "\n mode -- mode of matrix A" "\n 7 -- diagonal" "\n 8 -- block diagonal symmetric" "\n 9 -- block diagonal hermitian (complex only)" "\n nrowA -- # of rows in matrix A" "\n seed -- random number seed" "\n", argv[0]) ; return(0) ; } if ( (msglvl = atoi(argv[1])) < 0 ) { fprintf(stderr, "\n message level must be positive\n") ; exit(-1) ; } if ( strcmp(argv[2], "stdout") == 0 ) { msgFile = stdout ; } else if ( (msgFile = fopen(argv[2], "a")) == NULL ) { fprintf(stderr, "\n unable to open file %s\n", argv[2]) ; return(-1) ; } type = atoi(argv[3]) ; mode = atoi(argv[4]) ; nrowA = atoi(argv[5]) ; seed = atoi(argv[6]) ; fprintf(msgFile, "\n %% %s:" "\n %% msglvl = %d" "\n %% msgFile = %s" "\n %% type = %d" "\n %% mode = %d" "\n %% nrowA = %d" "\n %% seed = %d", argv[0], msglvl, argv[2], type, mode, nrowA, seed) ; /* ----------------------------- check for errors in the input ----------------------------- */ if ( nrowA <= 0 ) { fprintf(stderr, "\n invalid input\n") ; exit(-1) ; } /* -------------------------------------- initialize the random number generator -------------------------------------- */ drand = Drand_new() ; Drand_init(drand) ; Drand_setSeed(drand, seed) ; Drand_setNormal(drand, 0.0, 1.0) ; /* ---------------------------- initialize the X ZV objects ---------------------------- */ MARKTIME(t1) ; if ( type == SPOOLES_REAL ) { xdv0 = DV_new() ; DV_init(xdv0, nrowA, NULL) ; x0 = DV_entries(xdv0) ; Drand_fillDvector(drand, nrowA, x0) ; xdv1 = DV_new() ; DV_init(xdv1, nrowA, NULL) ; x1 = DV_entries(xdv1) ; Drand_fillDvector(drand, nrowA, x1) ; xdv2 = DV_new() ; DV_init(xdv2, nrowA, NULL) ; x2 = DV_entries(xdv2) ; Drand_fillDvector(drand, nrowA, x2) ; MARKTIME(t2) ; fprintf(msgFile, "\n %% CPU : %.3f to initialize X ZV objects", t2 - t1) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% X DV objects") ; fprintf(msgFile, "\n X0 = zeros(%d,1) ;", nrowA) ; DV_writeForMatlab(xdv0, "X0", msgFile) ; fprintf(msgFile, "\n X1 = zeros(%d,1) ;", nrowA) ; DV_writeForMatlab(xdv1, "X1", msgFile) ; fprintf(msgFile, "\n X2 = zeros(%d,1) ;", nrowA) ; DV_writeForMatlab(xdv2, "X2", msgFile) ; fflush(msgFile) ; } } else if ( type == SPOOLES_COMPLEX ) { xzv0 = ZV_new() ; ZV_init(xzv0, nrowA, NULL) ; x0 = ZV_entries(xzv0) ; Drand_fillDvector(drand, 2*nrowA, x0) ; xzv1 = ZV_new() ; ZV_init(xzv1, nrowA, NULL) ; x1 = ZV_entries(xzv1) ; Drand_fillDvector(drand, 2*nrowA, x1) ; xzv2 = ZV_new() ; ZV_init(xzv2, nrowA, NULL) ; x2 = ZV_entries(xzv2) ; Drand_fillDvector(drand, 2*nrowA, x2) ; MARKTIME(t2) ; fprintf(msgFile, "\n %% CPU : %.3f to initialize X ZV objects", t2 - t1) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% X ZV objects") ; fprintf(msgFile, "\n X0 = zeros(%d,1) ;", nrowA) ; ZV_writeForMatlab(xzv0, "X0", msgFile) ; fprintf(msgFile, "\n X1 = zeros(%d,1) ;", nrowA) ; ZV_writeForMatlab(xzv1, "X1", msgFile) ; fprintf(msgFile, "\n X2 = zeros(%d,1) ;", nrowA) ; ZV_writeForMatlab(xzv2, "X2", msgFile) ; fflush(msgFile) ; } } /* --------------------------------- initialize the Y DV or ZV objects --------------------------------- */ MARKTIME(t1) ; if ( type == SPOOLES_REAL ) { ydv0 = DV_new() ; DV_init(ydv0, nrowA, NULL) ; y0 = DV_entries(ydv0) ; ydv1 = DV_new() ; DV_init(ydv1, nrowA, NULL) ; y1 = DV_entries(ydv1) ; ydv2 = DV_new() ; DV_init(ydv2, nrowA, NULL) ; y2 = DV_entries(ydv2) ; MARKTIME(t2) ; fprintf(msgFile, "\n %% CPU : %.3f to initialize Y DV objects", t2 - t1) ; } else if ( type == SPOOLES_COMPLEX ) { yzv0 = ZV_new() ; ZV_init(yzv0, nrowA, NULL) ; y0 = ZV_entries(yzv0) ; yzv1 = ZV_new() ; ZV_init(yzv1, nrowA, NULL) ; y1 = ZV_entries(yzv1) ; yzv2 = ZV_new() ; ZV_init(yzv2, nrowA, NULL) ; y2 = ZV_entries(yzv2) ; MARKTIME(t2) ; fprintf(msgFile, "\n %% CPU : %.3f to initialize Y ZV objects", t2 - t1) ; } /* ----------------------------------- initialize the A matrix SubMtx object ----------------------------------- */ seed++ ; mtxA = SubMtx_new() ; switch ( mode ) { case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : case SUBMTX_BLOCK_DIAGONAL_HERM : SubMtx_initRandom(mtxA, type, mode, 0, 0, nrowA, nrowA, 0, seed) ; break ; default : fprintf(stderr, "\n fatal error in test_solve" "\n invalid mode = %d", mode) ; exit(-1) ; } if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% A SubMtx object") ; fprintf(msgFile, "\n A = zeros(%d,%d) ;", nrowA, nrowA) ; SubMtx_writeForMatlab(mtxA, "A", msgFile) ; fflush(msgFile) ; } /* ------------------- compute Y0 = A * X0 ------------------- */ if ( type == SPOOLES_REAL ) { DVzero(nrowA, y0) ; } else if ( type == SPOOLES_COMPLEX ) { DVzero(2*nrowA, y0) ; } SubMtx_scale1vec(mtxA, y0, x0) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n Z0 = zeros(%d,1) ;", nrowA) ; if ( type == SPOOLES_REAL ) { DV_writeForMatlab(ydv0, "Z0", msgFile) ; } else if ( type == SPOOLES_COMPLEX ) { ZV_writeForMatlab(yzv0, "Z0", msgFile) ; } fprintf(msgFile, "\n err0 = Z0 - A*X0 ;") ; fprintf(msgFile, "\n error0 = max(abs(err0))") ; fflush(msgFile) ; } if ( type == SPOOLES_REAL ) { DVzero(nrowA, y0) ; DVzero(nrowA, y1) ; } else if ( type == SPOOLES_COMPLEX ) { DVzero(2*nrowA, y0) ; DVzero(2*nrowA, y1) ; } SubMtx_scale2vec(mtxA, y0, y1, x0, x1) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n Z0 = zeros(%d,1) ;", nrowA) ; fprintf(msgFile, "\n\n Z1 = zeros(%d,1) ;", nrowA) ; if ( type == SPOOLES_REAL ) { DV_writeForMatlab(ydv0, "Z0", msgFile) ; DV_writeForMatlab(ydv1, "Z1", msgFile) ; } else if ( type == SPOOLES_COMPLEX ) { ZV_writeForMatlab(yzv0, "Z0", msgFile) ; ZV_writeForMatlab(yzv1, "Z1", msgFile) ; } fprintf(msgFile, "\n err1 = [Z0 Z1] - A*[X0 X1] ;") ; fprintf(msgFile, "\n error1 = max(abs(err1))") ; fflush(msgFile) ; } if ( type == SPOOLES_REAL ) { DVzero(nrowA, y0) ; DVzero(nrowA, y1) ; DVzero(nrowA, y2) ; } else if ( type == SPOOLES_COMPLEX ) { DVzero(2*nrowA, y0) ; DVzero(2*nrowA, y1) ; DVzero(2*nrowA, y2) ; } SubMtx_scale3vec(mtxA, y0, y1, y2, x0, x1, x2) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n Z0 = zeros(%d,1) ;", nrowA) ; fprintf(msgFile, "\n\n Z1 = zeros(%d,1) ;", nrowA) ; fprintf(msgFile, "\n\n Z2 = zeros(%d,1) ;", nrowA) ; if ( type == SPOOLES_REAL ) { DV_writeForMatlab(ydv0, "Z0", msgFile) ; DV_writeForMatlab(ydv1, "Z1", msgFile) ; DV_writeForMatlab(ydv2, "Z2", msgFile) ; } else if ( type == SPOOLES_COMPLEX ) { ZV_writeForMatlab(yzv0, "Z0", msgFile) ; ZV_writeForMatlab(yzv1, "Z1", msgFile) ; ZV_writeForMatlab(yzv2, "Z2", msgFile) ; } fprintf(msgFile, "\n err2 = [Z0 Z1 Z2] - A*[X0 X1 X2] ;") ; fprintf(msgFile, "\n error3 = max(abs(err2))") ; fflush(msgFile) ; } /* ------------------------ free the working storage ------------------------ */ SubMtx_free(mtxA) ; if ( type == SPOOLES_REAL ) { DV_free(xdv0) ; DV_free(xdv1) ; DV_free(xdv2) ; DV_free(ydv0) ; DV_free(ydv1) ; DV_free(ydv2) ; } else if ( type == SPOOLES_COMPLEX ) { ZV_free(xzv0) ; ZV_free(xzv1) ; ZV_free(xzv2) ; ZV_free(yzv0) ; ZV_free(yzv1) ; ZV_free(yzv2) ; } Drand_free(drand) ; fprintf(msgFile, "\n") ; return(1) ; }
/*--------------------------------------------------------------------*/ int main ( int argc, char *argv[] ) /* ----------------------------- test the SubMtx_solve() method. created -- 98apr15, cca ----------------------------- */ { SubMtx *mtxA, *mtxB, *mtxX ; double idot, rdot, t1, t2 ; double *entB, *entX ; Drand *drand ; FILE *msgFile ; int inc1, inc2, mode, msglvl, ncolA, nentA, nrowA, ncolB, nrowB, ncolX, nrowX, seed, type ; if ( argc != 9 ) { fprintf(stdout, "\n\n usage : %s msglvl msgFile type mode nrowA nentA ncolB seed" "\n msglvl -- message level" "\n msgFile -- message file" "\n type -- type of matrix A" "\n 1 -- real" "\n 2 -- complex" "\n mode -- mode of matrix A" "\n 2 -- sparse stored by rows" "\n 3 -- sparse stored by columns" "\n 5 -- sparse stored by subrows" "\n 6 -- sparse stored by subcolumns" "\n 7 -- diagonal" "\n 8 -- block diagonal symmetric" "\n 9 -- block diagonal hermitian" "\n nrowA -- # of rows in matrix A" "\n nentA -- # of entries in matrix A" "\n ncolB -- # of columns in matrix B" "\n seed -- random number seed" "\n", argv[0]) ; return(0) ; } if ( (msglvl = atoi(argv[1])) < 0 ) { fprintf(stderr, "\n message level must be positive\n") ; spoolesFatal(); } if ( strcmp(argv[2], "stdout") == 0 ) { msgFile = stdout ; } else if ( (msgFile = fopen(argv[2], "a")) == NULL ) { fprintf(stderr, "\n unable to open file %s\n", argv[2]) ; return(-1) ; } type = atoi(argv[3]) ; mode = atoi(argv[4]) ; nrowA = atoi(argv[5]) ; nentA = atoi(argv[6]) ; ncolB = atoi(argv[7]) ; seed = atoi(argv[8]) ; fprintf(msgFile, "\n %% %s:" "\n %% msglvl = %d" "\n %% msgFile = %s" "\n %% type = %d" "\n %% mode = %d" "\n %% nrowA = %d" "\n %% nentA = %d" "\n %% ncolB = %d" "\n %% seed = %d", argv[0], msglvl, argv[2], type, mode, nrowA, nentA, ncolB, seed) ; ncolA = nrowA ; nrowB = nrowA ; nrowX = nrowA ; ncolX = ncolB ; /* ----------------------------- check for errors in the input ----------------------------- */ if ( nrowA <= 0 || nentA <= 0 || ncolB <= 0 ) { fprintf(stderr, "\n invalid input\n") ; spoolesFatal(); } switch ( type ) { case SPOOLES_REAL : switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : break ; default : fprintf(stderr, "\n invalid mode %d\n", mode) ; spoolesFatal(); } break ; case SPOOLES_COMPLEX : switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : case SUBMTX_BLOCK_DIAGONAL_HERM : break ; default : fprintf(stderr, "\n invalid mode %d\n", mode) ; spoolesFatal(); } break ; default : fprintf(stderr, "\n invalid type %d\n", type) ; spoolesFatal(); break ; } /* -------------------------------------- initialize the random number generator -------------------------------------- */ drand = Drand_new() ; Drand_init(drand) ; Drand_setSeed(drand, seed) ; Drand_setNormal(drand, 0.0, 1.0) ; /* ------------------------------ initialize the X SubMtx object ------------------------------ */ MARKTIME(t1) ; mtxX = SubMtx_new() ; SubMtx_initRandom(mtxX, type, SUBMTX_DENSE_COLUMNS, 0, 0, nrowX, ncolX, nrowX*ncolX, ++seed) ; SubMtx_denseInfo(mtxX, &nrowX, &ncolX, &inc1, &inc2, &entX) ; MARKTIME(t2) ; fprintf(msgFile, "\n %% CPU : %.3f to initialize X SubMtx object", t2 - t1) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% X SubMtx object") ; fprintf(msgFile, "\n X = zeros(%d,%d) ;", nrowX, ncolX) ; SubMtx_writeForMatlab(mtxX, "X", msgFile) ; fflush(msgFile) ; } /* ------------------------------ initialize the B SubMtx object ------------------------------ */ MARKTIME(t1) ; mtxB = SubMtx_new() ; SubMtx_init(mtxB, type, SUBMTX_DENSE_COLUMNS, 0, 0, nrowB, ncolB, nrowB*ncolB) ; SubMtx_denseInfo(mtxB, &nrowB, &ncolB, &inc1, &inc2, &entB) ; switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : if ( SUBMTX_IS_REAL(mtxX) ) { DVcopy(nrowB*ncolB, entB, entX) ; } else if ( SUBMTX_IS_COMPLEX(mtxX) ) { ZVcopy(nrowB*ncolB, entB, entX) ; } break ; default : if ( SUBMTX_IS_REAL(mtxX) ) { DVzero(nrowB*ncolB, entB) ; } else if ( SUBMTX_IS_COMPLEX(mtxX) ) { DVzero(2*nrowB*ncolB, entB) ; } break ; } MARKTIME(t2) ; fprintf(msgFile, "\n %% CPU : %.3f to initialize B SubMtx object", t2 - t1) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% B SubMtx object") ; fprintf(msgFile, "\n B = zeros(%d,%d) ;", nrowB, ncolB) ; SubMtx_writeForMatlab(mtxB, "B", msgFile) ; fflush(msgFile) ; } /* ------------------------------------- initialize the A matrix SubMtx object ------------------------------------- */ seed++ ; mtxA = SubMtx_new() ; switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : SubMtx_initRandomLowerTriangle(mtxA, type, mode, 0, 0, nrowA, ncolA, nentA, seed, 1) ; break ; case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : SubMtx_initRandomUpperTriangle(mtxA, type, mode, 0, 0, nrowA, ncolA, nentA, seed, 1) ; break ; case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : case SUBMTX_BLOCK_DIAGONAL_HERM : SubMtx_initRandom(mtxA, type, mode, 0, 0, nrowA, ncolA, nentA, seed) ; break ; default : fprintf(stderr, "\n fatal error in test_solve" "\n invalid mode = %d", mode) ; spoolesFatal(); } if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% A SubMtx object") ; fprintf(msgFile, "\n A = zeros(%d,%d) ;", nrowA, ncolA) ; SubMtx_writeForMatlab(mtxA, "A", msgFile) ; fflush(msgFile) ; } /* -------------------------------------------------------- compute B = A * X (for diagonal and block diagonal) or B = (I + A) * X (for lower and upper triangular) -------------------------------------------------------- */ if ( SUBMTX_IS_REAL(mtxA) ) { DV *colDV, *rowDV ; double value, *colX, *rowA, *pBij, *pXij ; int irowA, jcolX ; colDV = DV_new() ; DV_init(colDV, nrowA, NULL) ; colX = DV_entries(colDV) ; rowDV = DV_new() ; DV_init(rowDV, nrowA, NULL) ; rowA = DV_entries(rowDV) ; for ( jcolX = 0 ; jcolX < ncolB ; jcolX++ ) { SubMtx_fillColumnDV(mtxX, jcolX, colDV) ; for ( irowA = 0 ; irowA < nrowA ; irowA++ ) { SubMtx_fillRowDV(mtxA, irowA, rowDV) ; SubMtx_locationOfRealEntry(mtxX, irowA, jcolX, &pXij) ; SubMtx_locationOfRealEntry(mtxB, irowA, jcolX, &pBij) ; value = DVdot(nrowA, rowA, colX) ; switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : *pBij = *pXij + value ; break ; case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : *pBij = value ; break ; } } } DV_free(colDV) ; DV_free(rowDV) ; } else if ( SUBMTX_IS_COMPLEX(mtxA) ) { ZV *colZV, *rowZV ; double *colX, *rowA, *pBIij, *pBRij, *pXIij, *pXRij ; int irowA, jcolX ; colZV = ZV_new() ; ZV_init(colZV, nrowA, NULL) ; colX = ZV_entries(colZV) ; rowZV = ZV_new() ; ZV_init(rowZV, nrowA, NULL) ; rowA = ZV_entries(rowZV) ; for ( jcolX = 0 ; jcolX < ncolB ; jcolX++ ) { SubMtx_fillColumnZV(mtxX, jcolX, colZV) ; for ( irowA = 0 ; irowA < nrowA ; irowA++ ) { SubMtx_fillRowZV(mtxA, irowA, rowZV) ; SubMtx_locationOfComplexEntry(mtxX, irowA, jcolX, &pXRij, &pXIij) ; SubMtx_locationOfComplexEntry(mtxB, irowA, jcolX, &pBRij, &pBIij) ; ZVdotU(nrowA, rowA, colX, &rdot, &idot) ; switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : *pBRij = *pXRij + rdot ; *pBIij = *pXIij + idot ; break ; case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : case SUBMTX_BLOCK_DIAGONAL_HERM : *pBRij = rdot ; *pBIij = idot ; break ; } } } ZV_free(colZV) ; ZV_free(rowZV) ; } /* ---------------------- print out the matrices ---------------------- */ if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% X SubMtx object") ; fprintf(msgFile, "\n X = zeros(%d,%d) ;", nrowX, ncolX) ; SubMtx_writeForMatlab(mtxX, "X", msgFile) ; fprintf(msgFile, "\n\n %% A SubMtx object") ; fprintf(msgFile, "\n A = zeros(%d,%d) ;", nrowA, ncolA) ; SubMtx_writeForMatlab(mtxA, "A", msgFile) ; fprintf(msgFile, "\n\n %% B SubMtx object") ; fprintf(msgFile, "\n B = zeros(%d,%d) ;", nrowB, ncolB) ; SubMtx_writeForMatlab(mtxB, "B", msgFile) ; fflush(msgFile) ; } /* ----------------- check with matlab ----------------- */ if ( msglvl > 1 ) { switch ( mode ) { case SUBMTX_DENSE_SUBROWS : case SUBMTX_SPARSE_ROWS : case SUBMTX_DENSE_SUBCOLUMNS : case SUBMTX_SPARSE_COLUMNS : fprintf(msgFile, "\n\n emtx = abs(B - X - A*X) ;" "\n\n condA = cond(eye(%d,%d) + A)" "\n\n maxabsZ = max(max(abs(emtx))) ", nrowA, nrowA) ; fflush(msgFile) ; break ; case SUBMTX_DIAGONAL : case SUBMTX_BLOCK_DIAGONAL_SYM : case SUBMTX_BLOCK_DIAGONAL_HERM : fprintf(msgFile, "\n\n emtx = abs(B - A*X) ;" "\n\n condA = cond(A)" "\n\n maxabsZ = max(max(abs(emtx))) ") ; fflush(msgFile) ; break ; } } /* ---------------------------------------- compute the solve DY = B or (I + A)Y = B ---------------------------------------- */ SubMtx_solve(mtxA, mtxB) ; if ( msglvl > 1 ) { fprintf(msgFile, "\n\n %% Y SubMtx object") ; fprintf(msgFile, "\n Y = zeros(%d,%d) ;", nrowB, ncolB) ; SubMtx_writeForMatlab(mtxB, "Y", msgFile) ; fprintf(msgFile, "\n\n %% solerror = abs(Y - X) ;" "\n\n solerror = abs(Y - X) ;" "\n\n maxabserror = max(max(solerror)) ") ; fflush(msgFile) ; } /* ------------------------ free the working storage ------------------------ */ SubMtx_free(mtxA) ; SubMtx_free(mtxX) ; SubMtx_free(mtxB) ; Drand_free(drand) ; fprintf(msgFile, "\n") ; return(1) ; }
/* ------------------------- total initializion method created -- 98jan22, cca ------------------------- */ void ZV_init2 ( ZV *zv, int size, int maxsize, int owned, double *vec ) { /* --------------- check the input --------------- */ if ( zv == NULL ) { fprintf(stderr, "\n fatal error in ZV_init2(%p,%d,%d,%d,%p)" "\n bad input\n", zv, size, maxsize, owned, vec) ; exit(-1) ; } if ( size < 0 || maxsize < size ) { fprintf(stderr, "\n fatal error in ZV_init2(%p,%d,%d,%d,%p)" "\n size = %d, maxsize = %d \n", zv, size, maxsize, owned, vec, size, maxsize) ; exit(-1) ; } if ( owned < 0 || 1 < owned ) { fprintf(stderr, "\n fatal error in ZV_init2(%p,%d,%d,%d,%p)" "\n owned = %d\n", zv, size, maxsize, owned, vec, owned) ; exit(-1) ; } if ( owned == 1 && vec == NULL ) { fprintf(stderr, "\n fatal error in ZV_init2(%p,%d,%d,%d,%p)" "\n owned = %d and vec = %p", zv, size, maxsize, owned, vec, owned, vec) ; exit(-1) ; } /* -------------- clear any data -------------- */ ZV_clearData(zv) ; if ( vec == NULL ) { /* ---------------------------------------------- no entries input, use the simplest initializer ---------------------------------------------- */ ZV_init(zv, size, NULL) ; } else { /* --------------------------------- entries are input, set the fields --------------------------------- */ zv->size = size ; zv->maxsize = maxsize ; zv->owned = owned ; zv->vec = vec ; } return ; }