seq/aijmkl/aijmkl.c

4a2a386eSRichard Tran Mills/*
4a2a386eSRichard Tran Mills  Defines basic operations for the MATSEQAIJMKL matrix class.
4a2a386eSRichard Tran Mills  This class is derived from the MATSEQAIJ class and retains the
4a2a386eSRichard Tran Mills  compressed row storage (aka Yale sparse matrix format) but uses
4a2a386eSRichard Tran Mills  sparse BLAS operations from the Intel Math Kernel Library (MKL)
4a2a386eSRichard Tran Mills  wherever possible.
4a2a386eSRichard Tran Mills*/
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#include <../src/mat/impls/aij/seq/aij.h>
4a2a386eSRichard Tran Mills#include <../src/mat/impls/aij/seq/aijmkl/aijmkl.h>
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills/* MKL include files. */
4a2a386eSRichard Tran Mills#include <mkl_spblas.h>  /* Sparse BLAS */
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Millstypedef struct {
c9d46305SRichard Tran Mills  PetscBool no_SpMV2;  /* If PETSC_TRUE, then don't use the MKL SpMV2 inspector-executor routines. */
4abfa3b3SRichard Tran Mills  PetscBool sparse_optimized; /* If PETSC_TRUE, then mkl_sparse_optimize() has been called. */
b8cbc1fbSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
df555b71SRichard Tran Mills  sparse_matrix_t csrA; /* "Handle" used by SpMV2 inspector-executor routines. */
df555b71SRichard Tran Mills  struct matrix_descr descr;
b8cbc1fbSRichard Tran Mills#endif
4a2a386eSRichard Tran Mills} Mat_SeqAIJMKL;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Millsextern PetscErrorCode MatAssemblyEnd_SeqAIJ(Mat,MatAssemblyType);
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatConvert_SeqAIJMKL_SeqAIJ"
4a2a386eSRichard Tran MillsPETSC_INTERN PetscErrorCode MatConvert_SeqAIJMKL_SeqAIJ(Mat A,MatType type,MatReuse reuse,Mat *newmat)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  /* This routine is only called to convert a MATAIJMKL to its base PETSc type, */
4a2a386eSRichard Tran Mills  /* so we will ignore 'MatType type'. */
4a2a386eSRichard Tran Mills  PetscErrorCode ierr;
4a2a386eSRichard Tran Mills  Mat            B       = *newmat;
4a2a386eSRichard Tran Mills  Mat_SeqAIJMKL *aijmkl=(Mat_SeqAIJMKL*)A->spptr;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  if (reuse == MAT_INITIAL_MATRIX) {
4a2a386eSRichard Tran Mills    ierr = MatDuplicate(A,MAT_COPY_VALUES,&B);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  }
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Reset the original function pointers. */
54871a98SRichard Tran Mills  B->ops->duplicate        = MatDuplicate_SeqAIJ;
4a2a386eSRichard Tran Mills  B->ops->assemblyend      = MatAssemblyEnd_SeqAIJ;
4a2a386eSRichard Tran Mills  B->ops->destroy          = MatDestroy_SeqAIJ;
54871a98SRichard Tran Mills  B->ops->mult             = MatMult_SeqAIJ;
ff03dc53SRichard Tran Mills  B->ops->multtranspose    = MatMultTranspose_SeqAIJ;
54871a98SRichard Tran Mills  B->ops->multadd          = MatMultAdd_SeqAIJ;
ff03dc53SRichard Tran Mills  B->ops->multtransposeadd = MatMultTransposeAdd_SeqAIJ;
4a2a386eSRichard Tran Mills
4abfa3b3SRichard Tran Mills  /* Free everything in the Mat_SeqAIJMKL data structure. Currently, this
4abfa3b3SRichard Tran Mills   * simply involves destroying the MKL sparse matrix handle.
4a2a386eSRichard Tran Mills   * We don't free the Mat_SeqAIJMKL struct itself, as this will
4a2a386eSRichard Tran Mills   * cause problems later when MatDestroy() tries to free it. */
4abfa3b3SRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
4abfa3b3SRichard Tran Mills  if (aijmkl->sparse_optimized) {
*0632b357SRichard Tran Mills    sparse_status_t stat;
4abfa3b3SRichard Tran Mills    stat = mkl_sparse_destroy(aijmkl->csrA);
4abfa3b3SRichard Tran Mills    if (stat != SPARSE_STATUS_SUCCESS) {
4abfa3b3SRichard Tran Mills      PetscFunctionReturn(PETSC_ERR_LIB);
4abfa3b3SRichard Tran Mills    }
4abfa3b3SRichard Tran Mills  }
4abfa3b3SRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Change the type of B to MATSEQAIJ. */
4a2a386eSRichard Tran Mills  ierr = PetscObjectChangeTypeName((PetscObject)B, MATSEQAIJ);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  *newmat = B;
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatDestroy_SeqAIJMKL"
4a2a386eSRichard Tran MillsPetscErrorCode MatDestroy_SeqAIJMKL(Mat A)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  PetscErrorCode ierr;
4a2a386eSRichard Tran Mills  Mat_SeqAIJMKL *aijmkl = (Mat_SeqAIJMKL*) A->spptr;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  /* Clean up everything in the Mat_SeqAIJMKL data structure, then free A->spptr. */
4abfa3b3SRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
4abfa3b3SRichard Tran Mills  if (aijmkl->sparse_optimized) {
4abfa3b3SRichard Tran Mills    sparse_status_t stat = SPARSE_STATUS_SUCCESS;
4abfa3b3SRichard Tran Mills    stat = mkl_sparse_destroy(aijmkl->csrA);
4abfa3b3SRichard Tran Mills    if (stat != SPARSE_STATUS_SUCCESS) {
4abfa3b3SRichard Tran Mills      PetscFunctionReturn(PETSC_ERR_LIB);
4abfa3b3SRichard Tran Mills    }
4abfa3b3SRichard Tran Mills  }
4abfa3b3SRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
4a2a386eSRichard Tran Mills  ierr = PetscFree(A->spptr);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Change the type of A back to SEQAIJ and use MatDestroy_SeqAIJ()
4a2a386eSRichard Tran Mills   * to destroy everything that remains. */
4a2a386eSRichard Tran Mills  ierr = PetscObjectChangeTypeName((PetscObject)A, MATSEQAIJ);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  /* Note that I don't call MatSetType().  I believe this is because that
4a2a386eSRichard Tran Mills   * is only to be called when *building* a matrix.  I could be wrong, but
4a2a386eSRichard Tran Mills   * that is how things work for the SuperLU matrix class. */
4a2a386eSRichard Tran Mills  ierr = MatDestroy_SeqAIJ(A);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatDuplicate_SeqAIJMKL"
4a2a386eSRichard Tran MillsPetscErrorCode MatDuplicate_SeqAIJMKL(Mat A, MatDuplicateOption op, Mat *M)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  PetscErrorCode ierr;
*0632b357SRichard Tran Mills  Mat_SeqAIJMKL *aijmkl;
*0632b357SRichard Tran Mills  Mat_SeqAIJMKL *aijmkl_dest;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  ierr = MatDuplicate_SeqAIJ(A,op,M);CHKERRQ(ierr);
*0632b357SRichard Tran Mills  aijmkl      = (Mat_SeqAIJMKL*) A->spptr;
*0632b357SRichard Tran Mills  aijmkl_dest = (Mat_SeqAIJMKL*) (*M)->spptr;
a9041576SRichard Tran Mills  ierr = PetscMemcpy(aijmkl_dest,aijmkl,sizeof(Mat_SeqAIJMKL));CHKERRQ(ierr);
*0632b357SRichard Tran Mills  aijmkl_dest->sparse_optimized = PETSC_FALSE;
*0632b357SRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
*0632b357SRichard Tran Mills  aijmkl_dest->csrA = NULL;
*0632b357SRichard Tran Mills  if (!aijmkl->no_SpMV2) {
*0632b357SRichard Tran Mills    sparse_status_t stat;
*0632b357SRichard Tran Mills    stat = mkl_sparse_copy(aijmkl->csrA,aijmkl->descr,&aijmkl_dest->csrA);
*0632b357SRichard Tran Mills    stat = mkl_sparse_optimize(aijmkl_dest->csrA);
*0632b357SRichard Tran Mills    if (stat != SPARSE_STATUS_SUCCESS) {
*0632b357SRichard Tran Mills      PetscFunctionReturn(PETSC_ERR_LIB);
*0632b357SRichard Tran Mills    }
*0632b357SRichard Tran Mills    aijmkl_dest->sparse_optimized = PETSC_TRUE;
*0632b357SRichard Tran Mills  }
*0632b357SRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatAssemblyEnd_SeqAIJMKL"
4a2a386eSRichard Tran MillsPetscErrorCode MatAssemblyEnd_SeqAIJMKL(Mat A, MatAssemblyType mode)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  PetscErrorCode  ierr;
4a2a386eSRichard Tran Mills  Mat_SeqAIJ      *a = (Mat_SeqAIJ*)A->data;
df555b71SRichard Tran Mills  Mat_SeqAIJMKL   *aijmkl;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  MatScalar       *aa;
df555b71SRichard Tran Mills  PetscInt        n;
df555b71SRichard Tran Mills  PetscInt        *aj,*ai;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  if (mode == MAT_FLUSH_ASSEMBLY) PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Since a MATSEQAIJMKL matrix is really just a MATSEQAIJ with some
4a2a386eSRichard Tran Mills   * extra information and some different methods, call the AssemblyEnd
4a2a386eSRichard Tran Mills   * routine for a MATSEQAIJ.
4a2a386eSRichard Tran Mills   * I'm not sure if this is the best way to do this, but it avoids
4a2a386eSRichard Tran Mills   * a lot of code duplication.
4a2a386eSRichard Tran Mills   * I also note that currently MATSEQAIJMKL doesn't know anything about
4a2a386eSRichard Tran Mills   * the Mat_CompressedRow data structure that SeqAIJ now uses when there
4a2a386eSRichard Tran Mills   * are many zero rows.  If the SeqAIJ assembly end routine decides to use
4a2a386eSRichard Tran Mills   * this, this may break things.  (Don't know... haven't looked at it.
4a2a386eSRichard Tran Mills   * Do I need to disable this somehow?) */
4a2a386eSRichard Tran Mills  a->inode.use = PETSC_FALSE;  /* Must disable: otherwise the MKL routines won't get used. */
4a2a386eSRichard Tran Mills  ierr         = MatAssemblyEnd_SeqAIJ(A, mode);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills
df555b71SRichard Tran Mills  aijmkl = (Mat_SeqAIJMKL*) A->spptr;
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
c9d46305SRichard Tran Mills  if (!aijmkl->no_SpMV2) {
*0632b357SRichard Tran Mills    sparse_status_t stat;
*0632b357SRichard Tran Mills    if (aijmkl->sparse_optimized) {
*0632b357SRichard Tran Mills      /* Matrix has been previously assembled and optimized. Must destroy old
*0632b357SRichard Tran Mills       * matrix handle before running the optimization step again. */
*0632b357SRichard Tran Mills      sparse_status_t stat;
*0632b357SRichard Tran Mills      stat = mkl_sparse_destroy(aijmkl->csrA);
*0632b357SRichard Tran Mills      if (stat != SPARSE_STATUS_SUCCESS) {
*0632b357SRichard Tran Mills        PetscFunctionReturn(PETSC_ERR_LIB);
*0632b357SRichard Tran Mills      }
*0632b357SRichard Tran Mills    }
c9d46305SRichard Tran Mills    /* Now perform the SpMV2 setup and matrix optimization. */
df555b71SRichard Tran Mills    aijmkl->descr.type        = SPARSE_MATRIX_TYPE_GENERAL;
df555b71SRichard Tran Mills    aijmkl->descr.mode        = SPARSE_FILL_MODE_LOWER;
df555b71SRichard Tran Mills    aijmkl->descr.diag        = SPARSE_DIAG_NON_UNIT;
df555b71SRichard Tran Mills    n = A->rmap->n;
df555b71SRichard Tran Mills    aj   = a->j;  /* aj[k] gives column index for element aa[k]. */
df555b71SRichard Tran Mills    aa   = a->a;  /* Nonzero elements stored row-by-row. */
df555b71SRichard Tran Mills    ai   = a->i;  /* ai[k] is the position in aa and aj where row k starts. */
df555b71SRichard Tran Mills    stat = mkl_sparse_x_create_csr (&aijmkl->csrA,SPARSE_INDEX_BASE_ZERO,n,n,ai,ai+1,aj,aa);
df555b71SRichard Tran Mills    stat = mkl_sparse_set_mv_hint(aijmkl->csrA,SPARSE_OPERATION_NON_TRANSPOSE,aijmkl->descr,1000);
df555b71SRichard Tran Mills    stat = mkl_sparse_set_memory_hint(aijmkl->csrA,SPARSE_MEMORY_AGGRESSIVE);
df555b71SRichard Tran Mills    stat = mkl_sparse_optimize(aijmkl->csrA);
df555b71SRichard Tran Mills    if (stat != SPARSE_STATUS_SUCCESS) {
df555b71SRichard Tran Mills      PetscFunctionReturn(PETSC_ERR_LIB);
df555b71SRichard Tran Mills    }
4abfa3b3SRichard Tran Mills    aijmkl->sparse_optimized = PETSC_TRUE;
c9d46305SRichard Tran Mills  }
d995685eSRichard Tran Mills#endif
df555b71SRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatMult_SeqAIJMKL"
4a2a386eSRichard Tran MillsPetscErrorCode MatMult_SeqAIJMKL(Mat A,Vec xx,Vec yy)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
4a2a386eSRichard Tran Mills  const PetscScalar *x;
4a2a386eSRichard Tran Mills  PetscScalar       *y;
4a2a386eSRichard Tran Mills  const MatScalar   *aa;
4a2a386eSRichard Tran Mills  PetscErrorCode    ierr;
4a2a386eSRichard Tran Mills  PetscInt          m=A->rmap->n;
4a2a386eSRichard Tran Mills  const PetscInt    *aj,*ai;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Variables not in MatMult_SeqAIJ. */
ff03dc53SRichard Tran Mills  char transa = 'n';  /* Used to indicate to MKL that we are not computing the transpose product. */
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  PetscFunctionBegin;
ff03dc53SRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  ierr = VecGetArray(yy,&y);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  aj   = a->j;  /* aj[k] gives column index for element aa[k]. */
ff03dc53SRichard Tran Mills  aa   = a->a;  /* Nonzero elements stored row-by-row. */
ff03dc53SRichard Tran Mills  ai   = a->i;  /* ai[k] is the position in aa and aj where row k starts. */
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  /* Call MKL sparse BLAS routine to do the MatMult. */
ff03dc53SRichard Tran Mills  mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,y);
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  PetscFunctionReturn(0);
ff03dc53SRichard Tran Mills}
ff03dc53SRichard Tran Mills
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
ff03dc53SRichard Tran Mills#undef __FUNCT__
df555b71SRichard Tran Mills#define __FUNCT__ "MatMult_SeqAIJMKL_SpMV2"
df555b71SRichard Tran MillsPetscErrorCode MatMult_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy)
df555b71SRichard Tran Mills{
df555b71SRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
df555b71SRichard Tran Mills  Mat_SeqAIJMKL     *aijmkl=(Mat_SeqAIJMKL*)A->spptr;
df555b71SRichard Tran Mills  const PetscScalar *x;
df555b71SRichard Tran Mills  PetscScalar       *y;
df555b71SRichard Tran Mills  PetscErrorCode    ierr;
df555b71SRichard Tran Mills  sparse_status_t stat = SPARSE_STATUS_SUCCESS;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  PetscFunctionBegin;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#ifdef DEBUG
df555b71SRichard Tran Mills  printf("DEBUG: In MatMult_SeqAIJMKL_SpMV2\n");
df555b71SRichard Tran Mills#endif
df555b71SRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecGetArray(yy,&y);CHKERRQ(ierr);
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  /* Call MKL SpMV2 executor routine to do the MatMult. */
df555b71SRichard Tran Mills  stat = mkl_sparse_x_mv(SPARSE_OPERATION_NON_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y);
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr);
df555b71SRichard Tran Mills  if (stat != SPARSE_STATUS_SUCCESS) {
df555b71SRichard Tran Mills    PetscFunctionReturn(PETSC_ERR_LIB);
df555b71SRichard Tran Mills  }
df555b71SRichard Tran Mills  PetscFunctionReturn(0);
df555b71SRichard Tran Mills}
d995685eSRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#undef __FUNCT__
ff03dc53SRichard Tran Mills#define __FUNCT__ "MatMultTranspose_SeqAIJMKL"
ff03dc53SRichard Tran MillsPetscErrorCode MatMultTranspose_SeqAIJMKL(Mat A,Vec xx,Vec yy)
ff03dc53SRichard Tran Mills{
ff03dc53SRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
ff03dc53SRichard Tran Mills  const PetscScalar *x;
ff03dc53SRichard Tran Mills  PetscScalar       *y;
ff03dc53SRichard Tran Mills  const MatScalar   *aa;
ff03dc53SRichard Tran Mills  PetscErrorCode    ierr;
ff03dc53SRichard Tran Mills  PetscInt          m=A->rmap->n;
ff03dc53SRichard Tran Mills  const PetscInt    *aj,*ai;
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  /* Variables not in MatMultTranspose_SeqAIJ. */
ff03dc53SRichard Tran Mills  char transa = 't';  /* Used to indicate to MKL that we are computing the transpose product. */
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = VecGetArray(yy,&y);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  aj   = a->j;  /* aj[k] gives column index for element aa[k]. */
4a2a386eSRichard Tran Mills  aa   = a->a;  /* Nonzero elements stored row-by-row. */
4a2a386eSRichard Tran Mills  ai   = a->i;  /* ai[k] is the position in aa and aj where row k starts. */
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Call MKL sparse BLAS routine to do the MatMult. */
4a2a386eSRichard Tran Mills  mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,y);
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
4a2a386eSRichard Tran Mills#undef __FUNCT__
df555b71SRichard Tran Mills#define __FUNCT__ "MatMultTranspose_SeqAIJMKL_SpMV2"
df555b71SRichard Tran MillsPetscErrorCode MatMultTranspose_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy)
df555b71SRichard Tran Mills{
df555b71SRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
df555b71SRichard Tran Mills  Mat_SeqAIJMKL     *aijmkl=(Mat_SeqAIJMKL*)A->spptr;
df555b71SRichard Tran Mills  const PetscScalar *x;
df555b71SRichard Tran Mills  PetscScalar       *y;
df555b71SRichard Tran Mills  PetscErrorCode    ierr;
*0632b357SRichard Tran Mills  sparse_status_t   stat;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  PetscFunctionBegin;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#ifdef DEBUG
df555b71SRichard Tran Mills  printf("DEBUG: In MatMultTranspose_SeqAIJMKL_SpMV2\n");
df555b71SRichard Tran Mills#endif
df555b71SRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecGetArray(yy,&y);CHKERRQ(ierr);
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  /* Call MKL SpMV2 executor routine to do the MatMultTranspose. */
df555b71SRichard Tran Mills  stat = mkl_sparse_x_mv(SPARSE_OPERATION_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y);
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr);
df555b71SRichard Tran Mills  if (stat != SPARSE_STATUS_SUCCESS) {
df555b71SRichard Tran Mills    PetscFunctionReturn(PETSC_ERR_LIB);
df555b71SRichard Tran Mills  }
df555b71SRichard Tran Mills  PetscFunctionReturn(0);
df555b71SRichard Tran Mills}
d995685eSRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatMultAdd_SeqAIJMKL"
4a2a386eSRichard Tran MillsPetscErrorCode MatMultAdd_SeqAIJMKL(Mat A,Vec xx,Vec yy,Vec zz)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
4a2a386eSRichard Tran Mills  const PetscScalar *x;
4a2a386eSRichard Tran Mills  PetscScalar       *y,*z;
4a2a386eSRichard Tran Mills  const MatScalar   *aa;
4a2a386eSRichard Tran Mills  PetscErrorCode    ierr;
4a2a386eSRichard Tran Mills  PetscInt          m=A->rmap->n;
4a2a386eSRichard Tran Mills  const PetscInt    *aj,*ai;
4a2a386eSRichard Tran Mills  PetscInt          i;
4a2a386eSRichard Tran Mills
ff03dc53SRichard Tran Mills  /* Variables not in MatMultAdd_SeqAIJ. */
ff03dc53SRichard Tran Mills  char transa = 'n';  /* Used to indicate to MKL that we are not computing the transpose product. */
a84739b8SRichard Tran Mills  PetscScalar       alpha = 1.0;
a84739b8SRichard Tran Mills  PetscScalar       beta = 1.0;
a84739b8SRichard Tran Mills  char              matdescra[6];
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  PetscFunctionBegin;
a84739b8SRichard Tran Mills  matdescra[0] = 'g';  /* Indicates to MKL that we using a general CSR matrix. */
a84739b8SRichard Tran Mills  matdescra[3] = 'c';  /* Indicates to MKL that we use C-style (0-based) indexing. */
a84739b8SRichard Tran Mills
ff03dc53SRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  aj   = a->j;  /* aj[k] gives column index for element aa[k]. */
ff03dc53SRichard Tran Mills  aa   = a->a;  /* Nonzero elements stored row-by-row. */
ff03dc53SRichard Tran Mills  ai   = a->i;  /* ai[k] is the position in aa and aj where row k starts. */
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  /* Call MKL sparse BLAS routine to do the MatMult. */
a84739b8SRichard Tran Mills  if (zz == yy) {
a84739b8SRichard Tran Mills    /* If zz and yy are the same vector, we can use MKL's mkl_xcsrmv(), which calculates y = alpha*A*x + beta*y. */
a84739b8SRichard Tran Mills    mkl_xcsrmv(&transa,&m,&m,&alpha,matdescra,aa,aj,ai,ai+1,x,&beta,y);
a84739b8SRichard Tran Mills  } else {
a84739b8SRichard Tran Mills    /* zz and yy are different vectors, so we call mkl_cspblas_xcsrgemv(), which calculates y = A*x, and then
a84739b8SRichard Tran Mills     * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */
ff03dc53SRichard Tran Mills    mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,z);
ff03dc53SRichard Tran Mills    for (i=0; i<m; i++) {
ff03dc53SRichard Tran Mills      z[i] += y[i];
ff03dc53SRichard Tran Mills    }
a84739b8SRichard Tran Mills  }
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
ff03dc53SRichard Tran Mills  PetscFunctionReturn(0);
ff03dc53SRichard Tran Mills}
ff03dc53SRichard Tran Mills
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
ff03dc53SRichard Tran Mills#undef __FUNCT__
df555b71SRichard Tran Mills#define __FUNCT__ "MatMultAdd_SeqAIJMKL_SpMV2"
df555b71SRichard Tran MillsPetscErrorCode MatMultAdd_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy,Vec zz)
df555b71SRichard Tran Mills{
df555b71SRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
df555b71SRichard Tran Mills  Mat_SeqAIJMKL     *aijmkl=(Mat_SeqAIJMKL*)A->spptr;
df555b71SRichard Tran Mills  const PetscScalar *x;
df555b71SRichard Tran Mills  PetscScalar       *y,*z;
df555b71SRichard Tran Mills  PetscErrorCode    ierr;
df555b71SRichard Tran Mills  PetscInt          m=A->rmap->n;
df555b71SRichard Tran Mills  PetscInt          i;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  /* Variables not in MatMultAdd_SeqAIJ. */
df555b71SRichard Tran Mills  sparse_status_t stat = SPARSE_STATUS_SUCCESS;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  PetscFunctionBegin;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#ifdef DEBUG
df555b71SRichard Tran Mills  printf("DEBUG: In MatMultAdd_SeqAIJMKL_SpMV2\n");
df555b71SRichard Tran Mills#endif
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  /* Call MKL sparse BLAS routine to do the MatMult. */
df555b71SRichard Tran Mills  if (zz == yy) {
df555b71SRichard Tran Mills    /* If zz and yy are the same vector, we can use mkl_sparse_x_mv, which calculates y = alpha*A*x + beta*y,
df555b71SRichard Tran Mills     * with alpha and beta both set to 1.0. */
df555b71SRichard Tran Mills    stat = mkl_sparse_x_mv(SPARSE_OPERATION_NON_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,1.0,y);
df555b71SRichard Tran Mills  } else {
df555b71SRichard Tran Mills    /* zz and yy are different vectors, so we call mkl_sparse_x_mv with alpha=1.0 and beta=0.0, and then
df555b71SRichard Tran Mills     * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */
df555b71SRichard Tran Mills    stat = mkl_sparse_x_mv(SPARSE_OPERATION_NON_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y);
df555b71SRichard Tran Mills    for (i=0; i<m; i++) {
df555b71SRichard Tran Mills      z[i] += y[i];
df555b71SRichard Tran Mills    }
df555b71SRichard Tran Mills  }
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
df555b71SRichard Tran Mills  if (stat != SPARSE_STATUS_SUCCESS) {
df555b71SRichard Tran Mills    PetscFunctionReturn(PETSC_ERR_LIB);
df555b71SRichard Tran Mills  }
df555b71SRichard Tran Mills  PetscFunctionReturn(0);
df555b71SRichard Tran Mills}
d995685eSRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#undef __FUNCT__
ff03dc53SRichard Tran Mills#define __FUNCT__ "MatMultTransposeAdd_SeqAIJMKL"
ff03dc53SRichard Tran MillsPetscErrorCode MatMultTransposeAdd_SeqAIJMKL(Mat A,Vec xx,Vec yy,Vec zz)
ff03dc53SRichard Tran Mills{
ff03dc53SRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
ff03dc53SRichard Tran Mills  const PetscScalar *x;
ff03dc53SRichard Tran Mills  PetscScalar       *y,*z;
ff03dc53SRichard Tran Mills  const MatScalar   *aa;
ff03dc53SRichard Tran Mills  PetscErrorCode    ierr;
ff03dc53SRichard Tran Mills  PetscInt          m=A->rmap->n;
ff03dc53SRichard Tran Mills  const PetscInt    *aj,*ai;
ff03dc53SRichard Tran Mills  PetscInt          i;
ff03dc53SRichard Tran Mills
ff03dc53SRichard Tran Mills  /* Variables not in MatMultTransposeAdd_SeqAIJ. */
ff03dc53SRichard Tran Mills  char transa = 't';  /* Used to indicate to MKL that we are computing the transpose product. */
a84739b8SRichard Tran Mills  PetscScalar       alpha = 1.0;
a84739b8SRichard Tran Mills  PetscScalar       beta = 1.0;
a84739b8SRichard Tran Mills  char              matdescra[6];
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
a84739b8SRichard Tran Mills  matdescra[0] = 'g';  /* Indicates to MKL that we using a general CSR matrix. */
a84739b8SRichard Tran Mills  matdescra[3] = 'c';  /* Indicates to MKL that we use C-style (0-based) indexing. */
a84739b8SRichard Tran Mills
4a2a386eSRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  aj   = a->j;  /* aj[k] gives column index for element aa[k]. */
4a2a386eSRichard Tran Mills  aa   = a->a;  /* Nonzero elements stored row-by-row. */
4a2a386eSRichard Tran Mills  ai   = a->i;  /* ai[k] is the position in aa and aj where row k starts. */
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  /* Call MKL sparse BLAS routine to do the MatMult. */
a84739b8SRichard Tran Mills  if (zz == yy) {
a84739b8SRichard Tran Mills    /* If zz and yy are the same vector, we can use MKL's mkl_xcsrmv(), which calculates y = alpha*A*x + beta*y. */
a84739b8SRichard Tran Mills    mkl_xcsrmv(&transa,&m,&m,&alpha,matdescra,aa,aj,ai,ai+1,x,&beta,y);
a84739b8SRichard Tran Mills  } else {
a84739b8SRichard Tran Mills    /* zz and yy are different vectors, so we call mkl_cspblas_xcsrgemv(), which calculates y = A*x, and then
a84739b8SRichard Tran Mills     * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */
4a2a386eSRichard Tran Mills    mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,z);
4a2a386eSRichard Tran Mills    for (i=0; i<m; i++) {
4a2a386eSRichard Tran Mills      z[i] += y[i];
4a2a386eSRichard Tran Mills    }
a84739b8SRichard Tran Mills  }
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
df555b71SRichard Tran Mills#undef __FUNCT__
df555b71SRichard Tran Mills#define __FUNCT__ "MatMultTransposeAdd_SeqAIJMKL_SpMV2"
df555b71SRichard Tran MillsPetscErrorCode MatMultTransposeAdd_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy,Vec zz)
df555b71SRichard Tran Mills{
df555b71SRichard Tran Mills  Mat_SeqAIJ        *a = (Mat_SeqAIJ*)A->data;
df555b71SRichard Tran Mills  Mat_SeqAIJMKL     *aijmkl=(Mat_SeqAIJMKL*)A->spptr;
df555b71SRichard Tran Mills  const PetscScalar *x;
df555b71SRichard Tran Mills  PetscScalar       *y,*z;
df555b71SRichard Tran Mills  PetscErrorCode    ierr;
df555b71SRichard Tran Mills  PetscInt          m=A->rmap->n;
df555b71SRichard Tran Mills  PetscInt          i;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  /* Variables not in MatMultTransposeAdd_SeqAIJ. */
df555b71SRichard Tran Mills  sparse_status_t stat = SPARSE_STATUS_SUCCESS;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  PetscFunctionBegin;
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills#ifdef DEBUG
df555b71SRichard Tran Mills  printf("DEBUG: In MatMultTransposeAdd_SeqAIJMKL_SpMV2\n");
df555b71SRichard Tran Mills#endif
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  /* Call MKL sparse BLAS routine to do the MatMult. */
df555b71SRichard Tran Mills  if (zz == yy) {
df555b71SRichard Tran Mills    /* If zz and yy are the same vector, we can use mkl_sparse_x_mv, which calculates y = alpha*A*x + beta*y,
df555b71SRichard Tran Mills     * with alpha and beta both set to 1.0. */
df555b71SRichard Tran Mills    stat = mkl_sparse_x_mv(SPARSE_OPERATION_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,1.0,y);
df555b71SRichard Tran Mills  } else {
df555b71SRichard Tran Mills    /* zz and yy are different vectors, so we call mkl_sparse_x_mv with alpha=1.0 and beta=0.0, and then
df555b71SRichard Tran Mills     * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */
df555b71SRichard Tran Mills    stat = mkl_sparse_x_mv(SPARSE_OPERATION_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y);
df555b71SRichard Tran Mills    for (i=0; i<m; i++) {
df555b71SRichard Tran Mills      z[i] += y[i];
df555b71SRichard Tran Mills    }
df555b71SRichard Tran Mills  }
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills  ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr);
df555b71SRichard Tran Mills  ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr);
df555b71SRichard Tran Mills  if (stat != SPARSE_STATUS_SUCCESS) {
df555b71SRichard Tran Mills    PetscFunctionReturn(PETSC_ERR_LIB);
df555b71SRichard Tran Mills  }
df555b71SRichard Tran Mills  PetscFunctionReturn(0);
df555b71SRichard Tran Mills}
d995685eSRichard Tran Mills#endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */
df555b71SRichard Tran Mills
df555b71SRichard Tran Mills
4a2a386eSRichard Tran Mills/* MatConvert_SeqAIJ_SeqAIJMKL converts a SeqAIJ matrix into a
4a2a386eSRichard Tran Mills * SeqAIJMKL matrix.  This routine is called by the MatCreate_SeqMKLAIJ()
4a2a386eSRichard Tran Mills * routine, but can also be used to convert an assembled SeqAIJ matrix
4a2a386eSRichard Tran Mills * into a SeqAIJMKL one. */
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatConvert_SeqAIJ_SeqAIJMKL"
4a2a386eSRichard Tran MillsPETSC_INTERN PetscErrorCode MatConvert_SeqAIJ_SeqAIJMKL(Mat A,MatType type,MatReuse reuse,Mat *newmat)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  PetscErrorCode ierr;
4a2a386eSRichard Tran Mills  Mat            B = *newmat;
4a2a386eSRichard Tran Mills  Mat_SeqAIJMKL *aijmkl;
c9d46305SRichard Tran Mills  PetscBool       set;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  if (reuse == MAT_INITIAL_MATRIX) {
4a2a386eSRichard Tran Mills    ierr = MatDuplicate(A,MAT_COPY_VALUES,&B);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  }
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  ierr     = PetscNewLog(B,&aijmkl);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  B->spptr = (void*) aijmkl;
4a2a386eSRichard Tran Mills
df555b71SRichard Tran Mills  /* Set function pointers for methods that we inherit from AIJ but override.
df555b71SRichard Tran Mills   * Currently the transposed operations are not being set because I encounter memory corruption
df555b71SRichard Tran Mills   * when these are enabled.  Need to look at this with Valgrind or similar. --RTM */
4a2a386eSRichard Tran Mills  B->ops->duplicate        = MatDuplicate_SeqAIJMKL;
4a2a386eSRichard Tran Mills  B->ops->assemblyend      = MatAssemblyEnd_SeqAIJMKL;
4a2a386eSRichard Tran Mills  B->ops->destroy          = MatDestroy_SeqAIJMKL;
c9d46305SRichard Tran Mills
4abfa3b3SRichard Tran Mills  aijmkl->sparse_optimized = PETSC_FALSE;
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
d995685eSRichard Tran Mills  aijmkl->no_SpMV2 = PETSC_FALSE;  /* Default to using the SpMV2 routines if our MKL supports them. */
d995685eSRichard Tran Mills#elif
d995685eSRichard Tran Mills  aijmkl->no_SpMV2 = PETSC_TRUE;
d995685eSRichard Tran Mills#endif
4abfa3b3SRichard Tran Mills
4abfa3b3SRichard Tran Mills  /* Parse command line options. */
c9d46305SRichard Tran Mills  ierr = PetscOptionsBegin(PetscObjectComm((PetscObject)A),((PetscObject)A)->prefix,"AIJMKL Options","Mat");CHKERRQ(ierr);
c9d46305SRichard Tran Mills  ierr = PetscOptionsBool("-mat_aijmkl_no_spmv2","NoSPMV2","None",(PetscBool)aijmkl->no_SpMV2,(PetscBool*)&aijmkl->no_SpMV2,&set);CHKERRQ(ierr);
c9d46305SRichard Tran Mills  ierr = PetscOptionsEnd();CHKERRQ(ierr);
d995685eSRichard Tran Mills#ifndef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
d995685eSRichard Tran Mills  if(!aijmkl->no_SpMV2) {
d995685eSRichard Tran Mills    ierr = PetscInfo(B,"User requested use of MKL SpMV2 routines, but MKL version does not support mkl_sparse_optimize();  defaulting to non-SpMV2 routines.\n");
d995685eSRichard Tran Mills    aijmkl->no_SpMV2 = PETSC_TRUE;
d995685eSRichard Tran Mills  }
d995685eSRichard Tran Mills#endif
c9d46305SRichard Tran Mills
c9d46305SRichard Tran Mills  if(!aijmkl->no_SpMV2) {
d995685eSRichard Tran Mills#ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE
df555b71SRichard Tran Mills    B->ops->mult             = MatMult_SeqAIJMKL_SpMV2;
df555b71SRichard Tran Mills    /* B->ops->multtranspose    = MatMultTranspose_SeqAIJMKL_SpMV2; */
df555b71SRichard Tran Mills    B->ops->multadd          = MatMultAdd_SeqAIJMKL_SpMV2;
df555b71SRichard Tran Mills    /* B->ops->multtransposeadd = MatMultTransposeAdd_SeqAIJMKL_SpMV2; */
d995685eSRichard Tran Mills#endif
c9d46305SRichard Tran Mills  } else {
4a2a386eSRichard Tran Mills    B->ops->mult             = MatMult_SeqAIJMKL;
c9d46305SRichard Tran Mills    /* B->ops->multtranspose    = MatMultTranspose_SeqAIJMKL; */
4a2a386eSRichard Tran Mills    B->ops->multadd          = MatMultAdd_SeqAIJMKL;
c9d46305SRichard Tran Mills    /* B->ops->multtransposeadd = MatMultTransposeAdd_SeqAIJMKL; */
c9d46305SRichard Tran Mills  }
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  ierr = PetscObjectComposeFunction((PetscObject)B,"MatConvert_seqaijmkl_seqaij_C",MatConvert_SeqAIJMKL_SeqAIJ);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  ierr    = PetscObjectChangeTypeName((PetscObject)B,MATSEQAIJMKL);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  *newmat = B;
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatCreateSeqAIJMKL"
4a2a386eSRichard Tran Mills/*@C
4a2a386eSRichard Tran Mills   MatCreateSeqAIJMKL - Creates a sparse matrix of type SEQAIJMKL.
4a2a386eSRichard Tran Mills   This type inherits from AIJ and is largely identical, but uses sparse BLAS
4a2a386eSRichard Tran Mills   routines from Intel MKL whenever possible.
4a2a386eSRichard Tran Mills   Collective on MPI_Comm
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills   Input Parameters:
4a2a386eSRichard Tran Mills+  comm - MPI communicator, set to PETSC_COMM_SELF
4a2a386eSRichard Tran Mills.  m - number of rows
4a2a386eSRichard Tran Mills.  n - number of columns
4a2a386eSRichard Tran Mills.  nz - number of nonzeros per row (same for all rows)
4a2a386eSRichard Tran Mills-  nnz - array containing the number of nonzeros in the various rows
4a2a386eSRichard Tran Mills         (possibly different for each row) or NULL
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills   Output Parameter:
4a2a386eSRichard Tran Mills.  A - the matrix
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills   Notes:
4a2a386eSRichard Tran Mills   If nnz is given then nz is ignored
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills   Level: intermediate
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills.keywords: matrix, cray, sparse, parallel
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills.seealso: MatCreate(), MatCreateMPIAIJMKL(), MatSetValues()
4a2a386eSRichard Tran Mills@*/
4a2a386eSRichard Tran MillsPetscErrorCode  MatCreateSeqAIJMKL(MPI_Comm comm,PetscInt m,PetscInt n,PetscInt nz,const PetscInt nnz[],Mat *A)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  PetscErrorCode ierr;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  ierr = MatCreate(comm,A);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = MatSetSizes(*A,m,n,m,n);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = MatSetType(*A,MATSEQAIJMKL);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = MatSeqAIJSetPreallocation_SeqAIJ(*A,nz,nnz);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills#undef __FUNCT__
4a2a386eSRichard Tran Mills#define __FUNCT__ "MatCreate_SeqAIJMKL"
4a2a386eSRichard Tran MillsPETSC_EXTERN PetscErrorCode MatCreate_SeqAIJMKL(Mat A)
4a2a386eSRichard Tran Mills{
4a2a386eSRichard Tran Mills  PetscErrorCode ierr;
4a2a386eSRichard Tran Mills
4a2a386eSRichard Tran Mills  PetscFunctionBegin;
4a2a386eSRichard Tran Mills  ierr = MatSetType(A,MATSEQAIJ);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  ierr = MatConvert_SeqAIJ_SeqAIJMKL(A,MATSEQAIJMKL,MAT_INPLACE_MATRIX,&A);CHKERRQ(ierr);
4a2a386eSRichard Tran Mills  PetscFunctionReturn(0);
4a2a386eSRichard Tran Mills}