#ifndef lint static char vcid[] = "$Id: dense.c,v 1.86 1996/01/02 20:15:45 bsmith Exp bsmith $"; #endif /* Defines the basic matrix operations for sequential dense. */ #include "dense.h" #include "pinclude/plapack.h" #include "pinclude/pviewer.h" int MatAXPY_SeqDense(Scalar *alpha,Mat X,Mat Y) { Mat_SeqDense *x = (Mat_SeqDense*) X->data,*y = (Mat_SeqDense*) Y->data; int N = x->m*x->n, one = 1; BLaxpy_( &N, alpha, x->v, &one, y->v, &one ); PLogFlops(2*N-1); return 0; } static int MatGetInfo_SeqDense(Mat A,MatInfoType flag,int *nz,int *nzalloc,int *mem) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int i,N = mat->m*mat->n,count = 0; Scalar *v = mat->v; for ( i=0; imem; return 0; } /* ---------------------------------------------------------------*/ /* COMMENT: I have chosen to hide column permutation in the pivots, rather than put it in the Mat->col slot.*/ static int MatLUFactor_SeqDense(Mat A,IS row,IS col,double f) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int info; if (!mat->pivots) { mat->pivots = (int *) PetscMalloc(mat->m*sizeof(int));CHKPTRQ(mat->pivots); PLogObjectMemory(A,mat->m*sizeof(int)); } LAgetrf_(&mat->m,&mat->n,mat->v,&mat->m,mat->pivots,&info); if (info) SETERRQ(1,"MatLUFactor_SeqDense:Bad LU factorization"); A->factor = FACTOR_LU; PLogFlops((2*mat->n*mat->n*mat->n)/3); return 0; } static int MatLUFactorSymbolic_SeqDense(Mat A,IS row,IS col,double f,Mat *fact) { return MatConvert(A,MATSAME,fact); } static int MatLUFactorNumeric_SeqDense(Mat A,Mat *fact) { return MatLUFactor(*fact,0,0,1.0); } static int MatCholeskyFactorSymbolic_SeqDense(Mat A,IS row,double f,Mat *fact) { return MatConvert(A,MATSAME,fact); } static int MatCholeskyFactorNumeric_SeqDense(Mat A,Mat *fact) { return MatCholeskyFactor(*fact,0,1.0); } static int MatCholeskyFactor_SeqDense(Mat A,IS perm,double f) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int info; if (mat->pivots) { PetscFree(mat->pivots); PLogObjectMemory(A,-mat->m*sizeof(int)); mat->pivots = 0; } LApotrf_("L",&mat->n,mat->v,&mat->m,&info); if (info) SETERRQ(1,"MatCholeskyFactor_SeqDense:Bad factorization"); A->factor = FACTOR_CHOLESKY; PLogFlops((mat->n*mat->n*mat->n)/3); return 0; } static int MatSolve_SeqDense(Mat A,Vec xx,Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int one = 1, info, ierr; Scalar *x, *y; ierr = VecGetArray(xx,&x); CHKERRQ(ierr); ierr = VecGetArray(yy,&y); CHKERRQ(ierr); PetscMemcpy(y,x,mat->m*sizeof(Scalar)); if (A->factor == FACTOR_LU) { LAgetrs_( "N", &mat->m, &one, mat->v, &mat->m, mat->pivots,y, &mat->m, &info ); } else if (A->factor == FACTOR_CHOLESKY){ LApotrs_( "L", &mat->m, &one, mat->v, &mat->m,y, &mat->m, &info ); } else SETERRQ(1,"MatSolve_SeqDense:Matrix must be factored to solve"); if (info) SETERRQ(1,"MatSolve_SeqDense:Bad solve"); PLogFlops(mat->n*mat->n - mat->n); return 0; } static int MatSolveTrans_SeqDense(Mat A,Vec xx,Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int one = 1, info; Scalar *x, *y; VecGetArray(xx,&x); VecGetArray(yy,&y); PetscMemcpy(y,x,mat->m*sizeof(Scalar)); /* assume if pivots exist then use LU; else Cholesky */ if (mat->pivots) { LAgetrs_( "T", &mat->m, &one, mat->v, &mat->m, mat->pivots,y, &mat->m, &info ); } else { LApotrs_( "L", &mat->m, &one, mat->v, &mat->m,y, &mat->m, &info ); } if (info) SETERRQ(1,"MatSolveTrans_SeqDense:Bad solve"); PLogFlops(mat->n*mat->n - mat->n); return 0; } static int MatSolveAdd_SeqDense(Mat A,Vec xx,Vec zz,Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int one = 1, info,ierr; Scalar *x, *y, sone = 1.0; Vec tmp = 0; VecGetArray(xx,&x); VecGetArray(yy,&y); if (yy == zz) { ierr = VecDuplicate(yy,&tmp); CHKERRQ(ierr); PLogObjectParent(A,tmp); ierr = VecCopy(yy,tmp); CHKERRQ(ierr); } PetscMemcpy(y,x,mat->m*sizeof(Scalar)); /* assume if pivots exist then use LU; else Cholesky */ if (mat->pivots) { LAgetrs_( "N", &mat->m, &one, mat->v, &mat->m, mat->pivots,y, &mat->m, &info ); } else { LApotrs_( "L", &mat->m, &one, mat->v, &mat->m,y, &mat->m, &info ); } if (info) SETERRQ(1,"MatSolveAdd_SeqDense:Bad solve"); if (tmp) {VecAXPY(&sone,tmp,yy); VecDestroy(tmp);} else VecAXPY(&sone,zz,yy); PLogFlops(mat->n*mat->n - mat->n); return 0; } static int MatSolveTransAdd_SeqDense(Mat A,Vec xx,Vec zz, Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int one = 1, info,ierr; Scalar *x, *y, sone = 1.0; Vec tmp; VecGetArray(xx,&x); VecGetArray(yy,&y); if (yy == zz) { ierr = VecDuplicate(yy,&tmp); CHKERRQ(ierr); PLogObjectParent(A,tmp); ierr = VecCopy(yy,tmp); CHKERRQ(ierr); } PetscMemcpy(y,x,mat->m*sizeof(Scalar)); /* assume if pivots exist then use LU; else Cholesky */ if (mat->pivots) { LAgetrs_( "T", &mat->m, &one, mat->v, &mat->m, mat->pivots,y, &mat->m, &info ); } else { LApotrs_( "L", &mat->m, &one, mat->v, &mat->m,y, &mat->m, &info ); } if (info) SETERRQ(1,"MatSolveTransAdd_SeqDense:Bad solve"); if (tmp) {VecAXPY(&sone,tmp,yy); VecDestroy(tmp);} else VecAXPY(&sone,zz,yy); PLogFlops(mat->n*mat->n - mat->n); return 0; } /* ------------------------------------------------------------------*/ static int MatRelax_SeqDense(Mat A,Vec bb,double omega,MatSORType flag, double shift,int its,Vec xx) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; Scalar *x, *b, *v = mat->v, zero = 0.0, xt; int o = 1,ierr, m = mat->m, i; if (flag & SOR_ZERO_INITIAL_GUESS) { /* this is a hack fix, should have another version without the second BLdot */ ierr = VecSet(&zero,xx); CHKERRQ(ierr); } VecGetArray(xx,&x); VecGetArray(bb,&b); while (its--) { if (flag & SOR_FORWARD_SWEEP){ for ( i=0; i=0; i-- ) { #if defined(PETSC_COMPLEX) /* cannot use BLAS dot for complex because compiler/linker is not happy about returning a double complex */ int _i; Scalar sum = b[i]; for ( _i=0; _idata; Scalar *v = mat->v, *x, *y; int _One=1;Scalar _DOne=1.0, _DZero=0.0; VecGetArray(xx,&x), VecGetArray(yy,&y); LAgemv_("T",&(mat->m),&(mat->n),&_DOne,v,&(mat->m),x,&_One,&_DZero,y,&_One); PLogFlops(2*mat->m*mat->n - mat->n); return 0; } static int MatMult_SeqDense(Mat A,Vec xx,Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; Scalar *v = mat->v, *x, *y; int _One=1;Scalar _DOne=1.0, _DZero=0.0; VecGetArray(xx,&x); VecGetArray(yy,&y); LAgemv_( "N", &(mat->m), &(mat->n), &_DOne, v, &(mat->m),x,&_One,&_DZero,y,&_One); PLogFlops(2*mat->m*mat->n - mat->m); return 0; } static int MatMultAdd_SeqDense(Mat A,Vec xx,Vec zz,Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; Scalar *v = mat->v, *x, *y, *z; int _One=1; Scalar _DOne=1.0; VecGetArray(xx,&x); VecGetArray(yy,&y); VecGetArray(zz,&z); if (zz != yy) PetscMemcpy(y,z,mat->m*sizeof(Scalar)); LAgemv_( "N", &(mat->m), &(mat->n),&_DOne,v,&(mat->m),x,&_One,&_DOne,y,&_One); PLogFlops(2*mat->m*mat->n); return 0; } static int MatMultTransAdd_SeqDense(Mat A,Vec xx,Vec zz,Vec yy) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; Scalar *v = mat->v, *x, *y, *z; int _One=1; Scalar _DOne=1.0; VecGetArray(xx,&x); VecGetArray(yy,&y); VecGetArray(zz,&z); if (zz != yy) PetscMemcpy(y,z,mat->m*sizeof(Scalar)); LAgemv_( "T", &(mat->m), &(mat->n), &_DOne, v, &(mat->m),x,&_One,&_DOne,y,&_One); PLogFlops(2*mat->m*mat->n); return 0; } /* -----------------------------------------------------------------*/ static int MatGetRow_SeqDense(Mat A,int row,int *ncols,int **cols,Scalar **vals) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; Scalar *v; int i; *ncols = mat->n; if (cols) { *cols = (int *) PetscMalloc(mat->n*sizeof(int)); CHKPTRQ(*cols); for ( i=0; in; i++ ) (*cols)[i] = i; } if (vals) { *vals = (Scalar *) PetscMalloc(mat->n*sizeof(Scalar)); CHKPTRQ(*vals); v = mat->v + row; for ( i=0; in; i++ ) {(*vals)[i] = *v; v += mat->m;} } return 0; } static int MatRestoreRow_SeqDense(Mat A,int row,int *ncols,int **cols,Scalar **vals) { if (cols) { PetscFree(*cols); } if (vals) { PetscFree(*vals); } return 0; } /* ----------------------------------------------------------------*/ static int MatSetValues_SeqDense(Mat A,int m,int *indexm,int n, int *indexn,Scalar *v,InsertMode addv) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int i,j; if (!mat->roworiented) { if (addv == INSERT_VALUES) { for ( j=0; jv[indexn[j]*mat->m + indexm[i]] = *v++; } } } else { for ( j=0; jv[indexn[j]*mat->m + indexm[i]] += *v++; } } } } else { if (addv == INSERT_VALUES) { for ( i=0; iv[indexn[j]*mat->m + indexm[i]] = *v++; } } } else { for ( i=0; iv[indexn[j]*mat->m + indexm[i]] += *v++; } } } } return 0; } static int MatGetValues_SeqDense(Mat A,int m,int *indexm,int n,int *indexn,Scalar *v) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int i, j; Scalar *vpt = v; /* row-oriented output */ for ( i=0; iv[indexn[j]*mat->m + indexm[i]]; } } return 0; } /* -----------------------------------------------------------------*/ static int MatConvertSameType_SeqDense(Mat A,Mat *newmat,int cpvalues) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data, *l; int ierr; Mat newi; ierr = MatCreateSeqDense(A->comm,mat->m,mat->n,PETSC_NULL,&newi); CHKERRQ(ierr); l = (Mat_SeqDense *) newi->data; if (cpvalues == COPY_VALUES) { PetscMemcpy(l->v,mat->v,mat->m*mat->n*sizeof(Scalar)); } *newmat = newi; return 0; } #include "sysio.h" int MatLoad_SeqDense(Viewer bview,MatType type,Mat *A) { Mat_SeqDense *a; Mat B; int *scols, i, j, nz, ierr, fd, header[4], size; int *rowlengths = 0, M, N, *cols; Scalar *vals, *svals, *v; PetscObject vobj = (PetscObject) bview; MPI_Comm comm = vobj->comm; MPI_Comm_size(comm,&size); if (size > 1) SETERRQ(1,"MatLoad_SeqDense: view must have one processor"); ierr = ViewerFileGetDescriptor_Private(bview,&fd); CHKERRQ(ierr); ierr = SYRead(fd,header,4,SYINT); CHKERRQ(ierr); if (header[0] != MAT_COOKIE) SETERRQ(1,"MatLoad_SeqDense:Not matrix object"); M = header[1]; N = header[2]; nz = header[3]; /* read row lengths */ rowlengths = (int*) PetscMalloc( M*sizeof(int) ); CHKPTRQ(rowlengths); ierr = SYRead(fd,rowlengths,M,SYINT); CHKERRQ(ierr); /* create our matrix */ ierr = MatCreateSeqDense(comm,M,N,PETSC_NULL,A); CHKERRQ(ierr); B = *A; a = (Mat_SeqDense *) B->data; v = a->v; /* read column indices and nonzeros */ cols = scols = (int *) PetscMalloc( nz*sizeof(int) ); CHKPTRQ(cols); ierr = SYRead(fd,cols,nz,SYINT); CHKERRQ(ierr); vals = svals = (Scalar *) PetscMalloc( nz*sizeof(Scalar) ); CHKPTRQ(vals); ierr = SYRead(fd,vals,nz,SYSCALAR); CHKERRQ(ierr); /* insert into matrix */ for ( i=0; idata; int ierr, i, j, format; FILE *fd; char *outputname; Scalar *v; ierr = ViewerFileGetPointer_Private(viewer,&fd); CHKERRQ(ierr); ierr = ViewerFileGetOutputname_Private(viewer,&outputname); CHKERRQ(ierr); ierr = ViewerFileGetFormat_Private(viewer,&format); if (format == FILE_FORMAT_INFO) { ; /* do nothing for now */ } else { for ( i=0; im; i++ ) { v = a->v + i; for ( j=0; jn; j++ ) { #if defined(PETSC_COMPLEX) fprintf(fd,"%6.4e + %6.4e i ",real(*v),imag(*v)); v += a->m; #else fprintf(fd,"%6.4e ",*v); v += a->m; #endif } fprintf(fd,"\n"); } } fflush(fd); return 0; } static int MatView_SeqDense_Binary(Mat A,Viewer viewer) { Mat_SeqDense *a = (Mat_SeqDense *) A->data; int ict, j, n = a->n, m = a->m, i, fd, *col_lens, ierr, nz = m*n; Scalar *v, *anonz; ierr = ViewerFileGetDescriptor_Private(viewer,&fd); CHKERRQ(ierr); col_lens = (int *) PetscMalloc( (4+nz)*sizeof(int) ); CHKPTRQ(col_lens); col_lens[0] = MAT_COOKIE; col_lens[1] = m; col_lens[2] = n; col_lens[3] = nz; /* store lengths of each row and write (including header) to file */ for ( i=0; iv + i; for ( j=0; jm; } } ierr = SYWrite(fd,anonz,nz,SYSCALAR,0); CHKERRQ(ierr); PetscFree(anonz); return 0; } static int MatView_SeqDense(PetscObject obj,Viewer viewer) { Mat A = (Mat) obj; Mat_SeqDense *a = (Mat_SeqDense*) A->data; PetscObject vobj = (PetscObject) viewer; if (!viewer) { viewer = STDOUT_VIEWER_SELF; vobj = (PetscObject) viewer; } if (vobj->cookie == VIEWER_COOKIE) { if (vobj->type == MATLAB_VIEWER) { return ViewerMatlabPutArray_Private(viewer,a->m,a->n,a->v); } else if (vobj->type == ASCII_FILE_VIEWER || vobj->type == ASCII_FILES_VIEWER) { return MatView_SeqDense_ASCII(A,viewer); } else if (vobj->type == BINARY_FILE_VIEWER) { return MatView_SeqDense_Binary(A,viewer); } } return 0; } static int MatDestroy_SeqDense(PetscObject obj) { Mat mat = (Mat) obj; Mat_SeqDense *l = (Mat_SeqDense *) mat->data; #if defined(PETSC_LOG) PLogObjectState(obj,"Rows %d Cols %d",l->m,l->n); #endif if (l->pivots) PetscFree(l->pivots); if (!l->user_alloc) PetscFree(l->v); PetscFree(l); PLogObjectDestroy(mat); PetscHeaderDestroy(mat); return 0; } static int MatTranspose_SeqDense(Mat A,Mat *matout) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int k, j, m, n; Scalar *v, tmp; v = mat->v; m = mat->m; n = mat->n; if (!matout) { /* in place transpose */ if (m != n) SETERRQ(1,"MatTranspose_SeqDense:Supports square matrix only in-place"); for ( j=0; jcomm,mat->n,mat->m,PETSC_NULL,&tmat); CHKERRQ(ierr); tmatd = (Mat_SeqDense *) tmat->data; v = mat->v; v2 = tmatd->v; for ( j=0; jdata; Mat_SeqDense *mat2 = (Mat_SeqDense *) A2->data; int i; Scalar *v1 = mat1->v, *v2 = mat2->v; if (mat1->m != mat2->m) return 0; if (mat1->n != mat2->n) return 0; for ( i=0; im*mat1->n; i++ ) { if (*v1 != *v2) return 0; v1++; v2++; } return 1; } static int MatGetDiagonal_SeqDense(Mat A,Vec v) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int i, n; Scalar *x; VecGetArray(v,&x); VecGetSize(v,&n); if (n != mat->m) SETERRQ(1,"MatGetDiagonal_SeqDense:Nonconforming mat and vec"); for ( i=0; im; i++ ) { x[i] = mat->v[i*mat->m + i]; } return 0; } static int MatScale_SeqDense(Mat A,Vec ll,Vec rr) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; Scalar *l,*r,x,*v; int i,j,m = mat->m, n = mat->n; if (ll) { VecGetArray(ll,&l); VecGetSize(ll,&m); if (m != mat->m) SETERRQ(1,"MatScale_SeqDense:Left scaling vec wrong size"); PLogFlops(n*m); for ( i=0; iv + i; for ( j=0; jn) SETERRQ(1,"MatScale_SeqDense:Right scaling vec wrong size"); PLogFlops(n*m); for ( i=0; iv + i*m; for ( j=0; jdata; Scalar *v = mat->v; double sum = 0.0; int i, j; if (type == NORM_FROBENIUS) { for (i=0; in*mat->m; i++ ) { #if defined(PETSC_COMPLEX) sum += real(conj(*v)*(*v)); v++; #else sum += (*v)*(*v); v++; #endif } *norm = sqrt(sum); PLogFlops(2*mat->n*mat->m); } else if (type == NORM_1) { *norm = 0.0; for ( j=0; jn; j++ ) { sum = 0.0; for ( i=0; im; i++ ) { sum += PetscAbsScalar(*v); v++; } if (sum > *norm) *norm = sum; } PLogFlops(mat->n*mat->m); } else if (type == NORM_INFINITY) { *norm = 0.0; for ( j=0; jm; j++ ) { v = mat->v + j; sum = 0.0; for ( i=0; in; i++ ) { sum += PetscAbsScalar(*v); v += mat->m; } if (sum > *norm) *norm = sum; } PLogFlops(mat->n*mat->m); } else { SETERRQ(1,"MatNorm_SeqDense:No two norm"); } return 0; } static int MatSetOption_SeqDense(Mat A,MatOption op) { Mat_SeqDense *aij = (Mat_SeqDense *) A->data; if (op == ROW_ORIENTED) aij->roworiented = 1; else if (op == COLUMN_ORIENTED) aij->roworiented = 0; else if (op == ROWS_SORTED || op == COLUMNS_SORTED || op == SYMMETRIC_MATRIX || op == STRUCTURALLY_SYMMETRIC_MATRIX || op == NO_NEW_NONZERO_LOCATIONS || op == YES_NEW_NONZERO_LOCATIONS || op == NO_NEW_DIAGONALS || op == YES_NEW_DIAGONALS) PLogInfo((PetscObject)A,"Info:MatSetOption_SeqDense:Option ignored\n"); else {SETERRQ(PETSC_ERR_SUP,"MatSetOption_SeqDense:unknown option");} return 0; } static int MatZeroEntries_SeqDense(Mat A) { Mat_SeqDense *l = (Mat_SeqDense *) A->data; PetscMemzero(l->v,l->m*l->n*sizeof(Scalar)); return 0; } static int MatZeroRows_SeqDense(Mat A,IS is,Scalar *diag) { Mat_SeqDense *l = (Mat_SeqDense *) A->data; int n = l->n, i, j,ierr,N, *rows; Scalar *slot; ierr = ISGetLocalSize(is,&N); CHKERRQ(ierr); ierr = ISGetIndices(is,&rows); CHKERRQ(ierr); for ( i=0; iv + rows[i]; for ( j=0; jv + (n+1)*rows[i]; *slot = *diag; } } ISRestoreIndices(is,&rows); return 0; } static int MatGetSize_SeqDense(Mat A,int *m,int *n) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; *m = mat->m; *n = mat->n; return 0; } static int MatGetOwnershipRange_SeqDense(Mat A,int *m,int *n) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; *m = 0; *n = mat->m; return 0; } static int MatGetArray_SeqDense(Mat A,Scalar **array) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; *array = mat->v; return 0; } static int MatGetSubMatrixInPlace_SeqDense(Mat A,IS isrow,IS iscol) { SETERRQ(1,"MatGetSubMatrixInPlace_SeqDense:not done"); } static int MatGetSubMatrix_SeqDense(Mat A,IS isrow,IS iscol,MatGetSubMatrixCall scall, Mat *submat) { Mat_SeqDense *mat = (Mat_SeqDense *) A->data; int nznew, *smap, i, j, ierr, oldcols = mat->n; int *irow, *icol, nrows, ncols, *cwork; Scalar *vwork, *val; Mat newmat; ierr = ISGetIndices(isrow,&irow); CHKERRQ(ierr); ierr = ISGetIndices(iscol,&icol); CHKERRQ(ierr); ierr = ISGetSize(isrow,&nrows); CHKERRQ(ierr); ierr = ISGetSize(iscol,&ncols); CHKERRQ(ierr); smap = (int *) PetscMalloc(oldcols*sizeof(int)); CHKPTRQ(smap); cwork = (int *) PetscMalloc(ncols*sizeof(int)); CHKPTRQ(cwork); vwork = (Scalar *) PetscMalloc(ncols*sizeof(Scalar)); CHKPTRQ(vwork); PetscMemzero((char*)smap,oldcols*sizeof(int)); for ( i=0; icomm,nrows,ncols,PETSC_NULL,&newmat); CHKERRQ(ierr); for (i=0; iv + irow[i]; for (j=0; jm]; } } ierr = MatSetValues(newmat,1,&i,nznew,cwork,vwork,INSERT_VALUES); CHKERRQ(ierr); } ierr = MatAssemblyBegin(newmat,FINAL_ASSEMBLY); CHKERRQ(ierr); ierr = MatAssemblyEnd(newmat,FINAL_ASSEMBLY); CHKERRQ(ierr); /* Free work space */ PetscFree(smap); PetscFree(cwork); PetscFree(vwork); ierr = ISRestoreIndices(isrow,&irow); CHKERRQ(ierr); ierr = ISRestoreIndices(iscol,&icol); CHKERRQ(ierr); *submat = newmat; return 0; } static int MatCopy_SeqDense(Mat A, Mat B) { Mat_SeqDense *a = (Mat_SeqDense *) A->data, *b = (Mat_SeqDense *)B->data; if (B->type != MATSEQDENSE) return MatCopy_Basic(A,B); if (a->m != b->m || a->n != b->n) SETERRQ(1,"MatCopy_SeqDense:size(B) != size(A)"); PetscMemcpy(b->v,a->v,a->m*a->n*sizeof(Scalar)); return 0; } /* -------------------------------------------------------------------*/ static struct _MatOps MatOps = {MatSetValues_SeqDense, MatGetRow_SeqDense, MatRestoreRow_SeqDense, MatMult_SeqDense, MatMultAdd_SeqDense, MatMultTrans_SeqDense, MatMultTransAdd_SeqDense, MatSolve_SeqDense,MatSolveAdd_SeqDense, MatSolveTrans_SeqDense,MatSolveTransAdd_SeqDense, MatLUFactor_SeqDense,MatCholeskyFactor_SeqDense, MatRelax_SeqDense, MatTranspose_SeqDense, MatGetInfo_SeqDense,MatEqual_SeqDense, MatGetDiagonal_SeqDense,MatScale_SeqDense,MatNorm_SeqDense, 0,0, 0, MatSetOption_SeqDense,MatZeroEntries_SeqDense,MatZeroRows_SeqDense,0, MatLUFactorSymbolic_SeqDense,MatLUFactorNumeric_SeqDense, MatCholeskyFactorSymbolic_SeqDense,MatCholeskyFactorNumeric_SeqDense, MatGetSize_SeqDense,MatGetSize_SeqDense,MatGetOwnershipRange_SeqDense, 0,0,MatGetArray_SeqDense,0,0, MatGetSubMatrix_SeqDense,MatGetSubMatrixInPlace_SeqDense, MatConvertSameType_SeqDense,0,0,0,0, MatAXPY_SeqDense,0,0, MatGetValues_SeqDense, MatCopy_SeqDense}; /*@C MatCreateSeqDense - Creates a sequential dense matrix that is stored in column major order (the usual Fortran 77 manner). Many of the matrix operations use the BLAS and LAPACK routines. Input Parameters: . comm - MPI communicator, set to MPI_COMM_SELF . m - number of rows . n - number of columns . data - optional location of matrix data. Set data=PETSC_NULL for PETSc to control all matrix memory allocation. Output Parameter: . newmat - the matrix Notes: The data input variable is intended primarily for Fortran programmers who wish to allocate their own matrix memory space. Most users should set data=PETSC_NULL. .keywords: dense, matrix, LAPACK, BLAS .seealso: MatCreate(), MatSetValues() @*/ int MatCreateSeqDense(MPI_Comm comm,int m,int n,Scalar *data,Mat *newmat) { Mat mat; Mat_SeqDense *l; int ierr,flg; *newmat = 0; PetscHeaderCreate(mat,_Mat,MAT_COOKIE,MATSEQDENSE,comm); PLogObjectCreate(mat); l = (Mat_SeqDense *) PetscMalloc(sizeof(Mat_SeqDense)); CHKPTRQ(l); PetscMemcpy(&mat->ops,&MatOps,sizeof(struct _MatOps)); mat->destroy = MatDestroy_SeqDense; mat->view = MatView_SeqDense; mat->factor = 0; PLogObjectMemory(mat,sizeof(struct _Mat)); mat->data = (void *) l; l->m = m; l->n = n; l->pivots = 0; l->roworiented = 1; if (data == PETSC_NULL) { l->v = (Scalar*) PetscMalloc((m*n+1)*sizeof(Scalar)); CHKPTRQ(l->v); PetscMemzero(l->v,m*n*sizeof(Scalar)); l->user_alloc = 0; PLogObjectMemory(mat,n*m*sizeof(Scalar)); } else { /* user-allocated storage */ l->v = data; l->user_alloc = 1; } ierr = OptionsHasName(PETSC_NULL,"-help",&flg); CHKERRQ(ierr); if (flg) { ierr = MatPrintHelp(mat); CHKERRQ(ierr); } *newmat = mat; return 0; } int MatCreate_SeqDense(Mat A,Mat *newmat) { Mat_SeqDense *m = (Mat_SeqDense *) A->data; return MatCreateSeqDense(A->comm,m->m,m->n,PETSC_NULL,newmat); }