14a2a386eSRichard Tran Mills /* 24a2a386eSRichard Tran Mills Defines basic operations for the MATSEQAIJMKL matrix class. 34a2a386eSRichard Tran Mills This class is derived from the MATSEQAIJ class and retains the 44a2a386eSRichard Tran Mills compressed row storage (aka Yale sparse matrix format) but uses 54a2a386eSRichard Tran Mills sparse BLAS operations from the Intel Math Kernel Library (MKL) 64a2a386eSRichard Tran Mills wherever possible. 74a2a386eSRichard Tran Mills */ 84a2a386eSRichard Tran Mills 94a2a386eSRichard Tran Mills #include <../src/mat/impls/aij/seq/aij.h> 104a2a386eSRichard Tran Mills #include <../src/mat/impls/aij/seq/aijmkl/aijmkl.h> 114a2a386eSRichard Tran Mills 124a2a386eSRichard Tran Mills /* MKL include files. */ 134a2a386eSRichard Tran Mills #include <mkl_spblas.h> /* Sparse BLAS */ 144a2a386eSRichard Tran Mills 154a2a386eSRichard Tran Mills typedef struct { 16c9d46305SRichard Tran Mills PetscBool no_SpMV2; /* If PETSC_TRUE, then don't use the MKL SpMV2 inspector-executor routines. */ 17df555b71SRichard Tran Mills sparse_matrix_t csrA; /* "Handle" used by SpMV2 inspector-executor routines. */ 18df555b71SRichard Tran Mills struct matrix_descr descr; 194a2a386eSRichard Tran Mills } Mat_SeqAIJMKL; 204a2a386eSRichard Tran Mills 214a2a386eSRichard Tran Mills extern PetscErrorCode MatAssemblyEnd_SeqAIJ(Mat,MatAssemblyType); 224a2a386eSRichard Tran Mills 234a2a386eSRichard Tran Mills #undef __FUNCT__ 244a2a386eSRichard Tran Mills #define __FUNCT__ "MatConvert_SeqAIJMKL_SeqAIJ" 254a2a386eSRichard Tran Mills PETSC_INTERN PetscErrorCode MatConvert_SeqAIJMKL_SeqAIJ(Mat A,MatType type,MatReuse reuse,Mat *newmat) 264a2a386eSRichard Tran Mills { 274a2a386eSRichard Tran Mills /* This routine is only called to convert a MATAIJMKL to its base PETSc type, */ 284a2a386eSRichard Tran Mills /* so we will ignore 'MatType type'. */ 294a2a386eSRichard Tran Mills PetscErrorCode ierr; 304a2a386eSRichard Tran Mills Mat B = *newmat; 314a2a386eSRichard Tran Mills Mat_SeqAIJMKL *aijmkl=(Mat_SeqAIJMKL*)A->spptr; 324a2a386eSRichard Tran Mills 334a2a386eSRichard Tran Mills PetscFunctionBegin; 344a2a386eSRichard Tran Mills if (reuse == MAT_INITIAL_MATRIX) { 354a2a386eSRichard Tran Mills ierr = MatDuplicate(A,MAT_COPY_VALUES,&B);CHKERRQ(ierr); 364a2a386eSRichard Tran Mills } 374a2a386eSRichard Tran Mills 384a2a386eSRichard Tran Mills /* Reset the original function pointers. */ 3954871a98SRichard Tran Mills B->ops->duplicate = MatDuplicate_SeqAIJ; 404a2a386eSRichard Tran Mills B->ops->assemblyend = MatAssemblyEnd_SeqAIJ; 414a2a386eSRichard Tran Mills B->ops->destroy = MatDestroy_SeqAIJ; 4254871a98SRichard Tran Mills B->ops->mult = MatMult_SeqAIJ; 43ff03dc53SRichard Tran Mills B->ops->multtranspose = MatMultTranspose_SeqAIJ; 4454871a98SRichard Tran Mills B->ops->multadd = MatMultAdd_SeqAIJ; 45ff03dc53SRichard Tran Mills B->ops->multtransposeadd = MatMultTransposeAdd_SeqAIJ; 464a2a386eSRichard Tran Mills 474a2a386eSRichard Tran Mills /* Free everything in the Mat_SeqAIJMKL data structure. 484a2a386eSRichard Tran Mills * We don't free the Mat_SeqAIJMKL struct itself, as this will 494a2a386eSRichard Tran Mills * cause problems later when MatDestroy() tries to free it. */ 504a2a386eSRichard Tran Mills /* Actually there is nothing to do here right now. 514a2a386eSRichard Tran Mills * When I've added use of the MKL SpMV2 inspector-executor routines, I should 524a2a386eSRichard Tran Mills * see if there is some way to clean up the "handle" used by SpMV2. */ 534a2a386eSRichard Tran Mills 544a2a386eSRichard Tran Mills /* Change the type of B to MATSEQAIJ. */ 554a2a386eSRichard Tran Mills ierr = PetscObjectChangeTypeName((PetscObject)B, MATSEQAIJ);CHKERRQ(ierr); 564a2a386eSRichard Tran Mills 574a2a386eSRichard Tran Mills *newmat = B; 584a2a386eSRichard Tran Mills PetscFunctionReturn(0); 594a2a386eSRichard Tran Mills } 604a2a386eSRichard Tran Mills 614a2a386eSRichard Tran Mills #undef __FUNCT__ 624a2a386eSRichard Tran Mills #define __FUNCT__ "MatDestroy_SeqAIJMKL" 634a2a386eSRichard Tran Mills PetscErrorCode MatDestroy_SeqAIJMKL(Mat A) 644a2a386eSRichard Tran Mills { 654a2a386eSRichard Tran Mills PetscErrorCode ierr; 664a2a386eSRichard Tran Mills Mat_SeqAIJMKL *aijmkl = (Mat_SeqAIJMKL*) A->spptr; 674a2a386eSRichard Tran Mills 684a2a386eSRichard Tran Mills PetscFunctionBegin; 694a2a386eSRichard Tran Mills /* Clean up everything in the Mat_SeqAIJMKL data structure, then free A->spptr. */ 704a2a386eSRichard Tran Mills mkl_sparse_destroy(aijmkl->csrA); 714a2a386eSRichard Tran Mills ierr = PetscFree(A->spptr);CHKERRQ(ierr); 724a2a386eSRichard Tran Mills 734a2a386eSRichard Tran Mills /* Change the type of A back to SEQAIJ and use MatDestroy_SeqAIJ() 744a2a386eSRichard Tran Mills * to destroy everything that remains. */ 754a2a386eSRichard Tran Mills ierr = PetscObjectChangeTypeName((PetscObject)A, MATSEQAIJ);CHKERRQ(ierr); 764a2a386eSRichard Tran Mills /* Note that I don't call MatSetType(). I believe this is because that 774a2a386eSRichard Tran Mills * is only to be called when *building* a matrix. I could be wrong, but 784a2a386eSRichard Tran Mills * that is how things work for the SuperLU matrix class. */ 794a2a386eSRichard Tran Mills ierr = MatDestroy_SeqAIJ(A);CHKERRQ(ierr); 804a2a386eSRichard Tran Mills PetscFunctionReturn(0); 814a2a386eSRichard Tran Mills } 824a2a386eSRichard Tran Mills 834a2a386eSRichard Tran Mills #undef __FUNCT__ 844a2a386eSRichard Tran Mills #define __FUNCT__ "MatDuplicate_SeqAIJMKL" 854a2a386eSRichard Tran Mills PetscErrorCode MatDuplicate_SeqAIJMKL(Mat A, MatDuplicateOption op, Mat *M) 864a2a386eSRichard Tran Mills { 874a2a386eSRichard Tran Mills PetscErrorCode ierr; 884a2a386eSRichard Tran Mills Mat_SeqAIJMKL *aijmkl = (Mat_SeqAIJMKL*) A->spptr; 894a2a386eSRichard Tran Mills Mat_SeqAIJMKL *aijmkl_dest = (Mat_SeqAIJMKL*) (*M)->spptr; 904a2a386eSRichard Tran Mills 914a2a386eSRichard Tran Mills PetscFunctionBegin; 924a2a386eSRichard Tran Mills ierr = MatDuplicate_SeqAIJ(A,op,M);CHKERRQ(ierr); 934a2a386eSRichard Tran Mills ierr = PetscMemcpy((*M)->spptr,aijmkl,sizeof(Mat_SeqAIJMKL));CHKERRQ(ierr); 944a2a386eSRichard Tran Mills PetscFunctionReturn(0); 954a2a386eSRichard Tran Mills } 964a2a386eSRichard Tran Mills 974a2a386eSRichard Tran Mills #undef __FUNCT__ 984a2a386eSRichard Tran Mills #define __FUNCT__ "MatAssemblyEnd_SeqAIJMKL" 994a2a386eSRichard Tran Mills PetscErrorCode MatAssemblyEnd_SeqAIJMKL(Mat A, MatAssemblyType mode) 1004a2a386eSRichard Tran Mills { 1014a2a386eSRichard Tran Mills PetscErrorCode ierr; 1024a2a386eSRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 103df555b71SRichard Tran Mills Mat_SeqAIJMKL *aijmkl; 104df555b71SRichard Tran Mills 105df555b71SRichard Tran Mills MatScalar *aa; 106df555b71SRichard Tran Mills PetscInt n; 107df555b71SRichard Tran Mills PetscInt *aj,*ai; 108df555b71SRichard Tran Mills sparse_status_t stat = SPARSE_STATUS_SUCCESS; 109c9d46305SRichard Tran Mills PetscBool set; 1104a2a386eSRichard Tran Mills 1114a2a386eSRichard Tran Mills PetscFunctionBegin; 1124a2a386eSRichard Tran Mills if (mode == MAT_FLUSH_ASSEMBLY) PetscFunctionReturn(0); 1134a2a386eSRichard Tran Mills 1144a2a386eSRichard Tran Mills /* Since a MATSEQAIJMKL matrix is really just a MATSEQAIJ with some 1154a2a386eSRichard Tran Mills * extra information and some different methods, call the AssemblyEnd 1164a2a386eSRichard Tran Mills * routine for a MATSEQAIJ. 1174a2a386eSRichard Tran Mills * I'm not sure if this is the best way to do this, but it avoids 1184a2a386eSRichard Tran Mills * a lot of code duplication. 1194a2a386eSRichard Tran Mills * I also note that currently MATSEQAIJMKL doesn't know anything about 1204a2a386eSRichard Tran Mills * the Mat_CompressedRow data structure that SeqAIJ now uses when there 1214a2a386eSRichard Tran Mills * are many zero rows. If the SeqAIJ assembly end routine decides to use 1224a2a386eSRichard Tran Mills * this, this may break things. (Don't know... haven't looked at it. 1234a2a386eSRichard Tran Mills * Do I need to disable this somehow?) */ 1244a2a386eSRichard Tran Mills a->inode.use = PETSC_FALSE; /* Must disable: otherwise the MKL routines won't get used. */ 1254a2a386eSRichard Tran Mills ierr = MatAssemblyEnd_SeqAIJ(A, mode);CHKERRQ(ierr); 1264a2a386eSRichard Tran Mills 127df555b71SRichard Tran Mills aijmkl = (Mat_SeqAIJMKL*) A->spptr; 128*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 129c9d46305SRichard Tran Mills if (!aijmkl->no_SpMV2) { 130c9d46305SRichard Tran Mills /* Now perform the SpMV2 setup and matrix optimization. */ 131df555b71SRichard Tran Mills aijmkl->descr.type = SPARSE_MATRIX_TYPE_GENERAL; 132df555b71SRichard Tran Mills aijmkl->descr.mode = SPARSE_FILL_MODE_LOWER; 133df555b71SRichard Tran Mills aijmkl->descr.diag = SPARSE_DIAG_NON_UNIT; 134df555b71SRichard Tran Mills n = A->rmap->n; 135df555b71SRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 136df555b71SRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 137df555b71SRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 138df555b71SRichard Tran Mills stat = mkl_sparse_x_create_csr (&aijmkl->csrA,SPARSE_INDEX_BASE_ZERO,n,n,ai,ai+1,aj,aa); 139df555b71SRichard Tran Mills stat = mkl_sparse_set_mv_hint(aijmkl->csrA,SPARSE_OPERATION_NON_TRANSPOSE,aijmkl->descr,1000); 140df555b71SRichard Tran Mills stat = mkl_sparse_set_memory_hint(aijmkl->csrA,SPARSE_MEMORY_AGGRESSIVE); 141df555b71SRichard Tran Mills stat = mkl_sparse_optimize(aijmkl->csrA); 142df555b71SRichard Tran Mills if (stat != SPARSE_STATUS_SUCCESS) { 143df555b71SRichard Tran Mills PetscFunctionReturn(PETSC_ERR_LIB); 144df555b71SRichard Tran Mills } 145c9d46305SRichard Tran Mills } 146*d995685eSRichard Tran Mills #endif 147df555b71SRichard Tran Mills 1484a2a386eSRichard Tran Mills PetscFunctionReturn(0); 1494a2a386eSRichard Tran Mills } 1504a2a386eSRichard Tran Mills 1514a2a386eSRichard Tran Mills #undef __FUNCT__ 1524a2a386eSRichard Tran Mills #define __FUNCT__ "MatMult_SeqAIJMKL" 1534a2a386eSRichard Tran Mills PetscErrorCode MatMult_SeqAIJMKL(Mat A,Vec xx,Vec yy) 1544a2a386eSRichard Tran Mills { 1554a2a386eSRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 1564a2a386eSRichard Tran Mills const PetscScalar *x; 1574a2a386eSRichard Tran Mills PetscScalar *y; 1584a2a386eSRichard Tran Mills const MatScalar *aa; 1594a2a386eSRichard Tran Mills PetscErrorCode ierr; 1604a2a386eSRichard Tran Mills PetscInt m=A->rmap->n; 1614a2a386eSRichard Tran Mills const PetscInt *aj,*ai; 1624a2a386eSRichard Tran Mills PetscInt i; 1634a2a386eSRichard Tran Mills 1644a2a386eSRichard Tran Mills /* Variables not in MatMult_SeqAIJ. */ 165ff03dc53SRichard Tran Mills char transa = 'n'; /* Used to indicate to MKL that we are not computing the transpose product. */ 166ff03dc53SRichard Tran Mills 167ff03dc53SRichard Tran Mills PetscFunctionBegin; 168ff03dc53SRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 169ff03dc53SRichard Tran Mills ierr = VecGetArray(yy,&y);CHKERRQ(ierr); 170ff03dc53SRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 171ff03dc53SRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 172ff03dc53SRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 173ff03dc53SRichard Tran Mills 174ff03dc53SRichard Tran Mills /* Call MKL sparse BLAS routine to do the MatMult. */ 175ff03dc53SRichard Tran Mills mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,y); 176ff03dc53SRichard Tran Mills 177ff03dc53SRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr); 178ff03dc53SRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 179ff03dc53SRichard Tran Mills ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); 180ff03dc53SRichard Tran Mills PetscFunctionReturn(0); 181ff03dc53SRichard Tran Mills } 182ff03dc53SRichard Tran Mills 183*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 184ff03dc53SRichard Tran Mills #undef __FUNCT__ 185df555b71SRichard Tran Mills #define __FUNCT__ "MatMult_SeqAIJMKL_SpMV2" 186df555b71SRichard Tran Mills PetscErrorCode MatMult_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy) 187df555b71SRichard Tran Mills { 188df555b71SRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 189df555b71SRichard Tran Mills Mat_SeqAIJMKL *aijmkl=(Mat_SeqAIJMKL*)A->spptr; 190df555b71SRichard Tran Mills const PetscScalar *x; 191df555b71SRichard Tran Mills PetscScalar *y; 192df555b71SRichard Tran Mills const MatScalar *aa; 193df555b71SRichard Tran Mills PetscErrorCode ierr; 194df555b71SRichard Tran Mills sparse_status_t stat = SPARSE_STATUS_SUCCESS; 195df555b71SRichard Tran Mills 196df555b71SRichard Tran Mills PetscFunctionBegin; 197df555b71SRichard Tran Mills 198df555b71SRichard Tran Mills #ifdef DEBUG 199df555b71SRichard Tran Mills printf("DEBUG: In MatMult_SeqAIJMKL_SpMV2\n"); 200df555b71SRichard Tran Mills #endif 201df555b71SRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 202df555b71SRichard Tran Mills ierr = VecGetArray(yy,&y);CHKERRQ(ierr); 203df555b71SRichard Tran Mills 204df555b71SRichard Tran Mills /* Call MKL SpMV2 executor routine to do the MatMult. */ 205df555b71SRichard Tran Mills stat = mkl_sparse_x_mv(SPARSE_OPERATION_NON_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y); 206df555b71SRichard Tran Mills 207df555b71SRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr); 208df555b71SRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 209df555b71SRichard Tran Mills ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); 210df555b71SRichard Tran Mills if (stat != SPARSE_STATUS_SUCCESS) { 211df555b71SRichard Tran Mills PetscFunctionReturn(PETSC_ERR_LIB); 212df555b71SRichard Tran Mills } 213df555b71SRichard Tran Mills PetscFunctionReturn(0); 214df555b71SRichard Tran Mills } 215*d995685eSRichard Tran Mills #endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */ 216df555b71SRichard Tran Mills 217df555b71SRichard Tran Mills #undef __FUNCT__ 218ff03dc53SRichard Tran Mills #define __FUNCT__ "MatMultTranspose_SeqAIJMKL" 219ff03dc53SRichard Tran Mills PetscErrorCode MatMultTranspose_SeqAIJMKL(Mat A,Vec xx,Vec yy) 220ff03dc53SRichard Tran Mills { 221ff03dc53SRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 222ff03dc53SRichard Tran Mills const PetscScalar *x; 223ff03dc53SRichard Tran Mills PetscScalar *y; 224ff03dc53SRichard Tran Mills const MatScalar *aa; 225ff03dc53SRichard Tran Mills PetscErrorCode ierr; 226ff03dc53SRichard Tran Mills PetscInt m=A->rmap->n; 227ff03dc53SRichard Tran Mills const PetscInt *aj,*ai; 228ff03dc53SRichard Tran Mills PetscInt i; 229ff03dc53SRichard Tran Mills 230ff03dc53SRichard Tran Mills /* Variables not in MatMultTranspose_SeqAIJ. */ 231ff03dc53SRichard Tran Mills char transa = 't'; /* Used to indicate to MKL that we are computing the transpose product. */ 2324a2a386eSRichard Tran Mills 2334a2a386eSRichard Tran Mills PetscFunctionBegin; 2344a2a386eSRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 2354a2a386eSRichard Tran Mills ierr = VecGetArray(yy,&y);CHKERRQ(ierr); 2364a2a386eSRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 2374a2a386eSRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 2384a2a386eSRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 2394a2a386eSRichard Tran Mills 2404a2a386eSRichard Tran Mills /* Call MKL sparse BLAS routine to do the MatMult. */ 2414a2a386eSRichard Tran Mills mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,y); 2424a2a386eSRichard Tran Mills 2434a2a386eSRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr); 2444a2a386eSRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 2454a2a386eSRichard Tran Mills ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); 2464a2a386eSRichard Tran Mills PetscFunctionReturn(0); 2474a2a386eSRichard Tran Mills } 2484a2a386eSRichard Tran Mills 249*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 2504a2a386eSRichard Tran Mills #undef __FUNCT__ 251df555b71SRichard Tran Mills #define __FUNCT__ "MatMultTranspose_SeqAIJMKL_SpMV2" 252df555b71SRichard Tran Mills PetscErrorCode MatMultTranspose_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy) 253df555b71SRichard Tran Mills { 254df555b71SRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 255df555b71SRichard Tran Mills Mat_SeqAIJMKL *aijmkl=(Mat_SeqAIJMKL*)A->spptr; 256df555b71SRichard Tran Mills const PetscScalar *x; 257df555b71SRichard Tran Mills PetscScalar *y; 258df555b71SRichard Tran Mills const MatScalar *aa; 259df555b71SRichard Tran Mills PetscErrorCode ierr; 260df555b71SRichard Tran Mills sparse_status_t stat = SPARSE_STATUS_SUCCESS; 261df555b71SRichard Tran Mills 262df555b71SRichard Tran Mills PetscFunctionBegin; 263df555b71SRichard Tran Mills 264df555b71SRichard Tran Mills #ifdef DEBUG 265df555b71SRichard Tran Mills printf("DEBUG: In MatMultTranspose_SeqAIJMKL_SpMV2\n"); 266df555b71SRichard Tran Mills #endif 267df555b71SRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 268df555b71SRichard Tran Mills ierr = VecGetArray(yy,&y);CHKERRQ(ierr); 269df555b71SRichard Tran Mills 270df555b71SRichard Tran Mills /* Call MKL SpMV2 executor routine to do the MatMultTranspose. */ 271df555b71SRichard Tran Mills stat = mkl_sparse_x_mv(SPARSE_OPERATION_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y); 272df555b71SRichard Tran Mills 273df555b71SRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz - a->nonzerorowcnt);CHKERRQ(ierr); 274df555b71SRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 275df555b71SRichard Tran Mills ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); 276df555b71SRichard Tran Mills if (stat != SPARSE_STATUS_SUCCESS) { 277df555b71SRichard Tran Mills PetscFunctionReturn(PETSC_ERR_LIB); 278df555b71SRichard Tran Mills } 279df555b71SRichard Tran Mills PetscFunctionReturn(0); 280df555b71SRichard Tran Mills } 281*d995685eSRichard Tran Mills #endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */ 282df555b71SRichard Tran Mills 283df555b71SRichard Tran Mills #undef __FUNCT__ 2844a2a386eSRichard Tran Mills #define __FUNCT__ "MatMultAdd_SeqAIJMKL" 2854a2a386eSRichard Tran Mills PetscErrorCode MatMultAdd_SeqAIJMKL(Mat A,Vec xx,Vec yy,Vec zz) 2864a2a386eSRichard Tran Mills { 2874a2a386eSRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 2884a2a386eSRichard Tran Mills const PetscScalar *x; 2894a2a386eSRichard Tran Mills PetscScalar *y,*z; 2904a2a386eSRichard Tran Mills const MatScalar *aa; 2914a2a386eSRichard Tran Mills PetscErrorCode ierr; 2924a2a386eSRichard Tran Mills PetscInt m=A->rmap->n; 2934a2a386eSRichard Tran Mills const PetscInt *aj,*ai; 2944a2a386eSRichard Tran Mills PetscInt i; 2954a2a386eSRichard Tran Mills 296ff03dc53SRichard Tran Mills /* Variables not in MatMultAdd_SeqAIJ. */ 297ff03dc53SRichard Tran Mills char transa = 'n'; /* Used to indicate to MKL that we are not computing the transpose product. */ 298a84739b8SRichard Tran Mills PetscScalar alpha = 1.0; 299a84739b8SRichard Tran Mills PetscScalar beta = 1.0; 300a84739b8SRichard Tran Mills char matdescra[6]; 301ff03dc53SRichard Tran Mills 302ff03dc53SRichard Tran Mills PetscFunctionBegin; 303a84739b8SRichard Tran Mills matdescra[0] = 'g'; /* Indicates to MKL that we using a general CSR matrix. */ 304a84739b8SRichard Tran Mills matdescra[3] = 'c'; /* Indicates to MKL that we use C-style (0-based) indexing. */ 305a84739b8SRichard Tran Mills 306ff03dc53SRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 307ff03dc53SRichard Tran Mills ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 308ff03dc53SRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 309ff03dc53SRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 310ff03dc53SRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 311ff03dc53SRichard Tran Mills 312ff03dc53SRichard Tran Mills /* Call MKL sparse BLAS routine to do the MatMult. */ 313a84739b8SRichard Tran Mills if (zz == yy) { 314a84739b8SRichard 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. */ 315a84739b8SRichard Tran Mills mkl_xcsrmv(&transa,&m,&m,&alpha,matdescra,aa,aj,ai,ai+1,x,&beta,y); 316a84739b8SRichard Tran Mills } else { 317a84739b8SRichard Tran Mills /* zz and yy are different vectors, so we call mkl_cspblas_xcsrgemv(), which calculates y = A*x, and then 318a84739b8SRichard Tran Mills * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */ 319ff03dc53SRichard Tran Mills mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,z); 320ff03dc53SRichard Tran Mills for (i=0; i<m; i++) { 321ff03dc53SRichard Tran Mills z[i] += y[i]; 322ff03dc53SRichard Tran Mills } 323a84739b8SRichard Tran Mills } 324ff03dc53SRichard Tran Mills 325ff03dc53SRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr); 326ff03dc53SRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 327ff03dc53SRichard Tran Mills ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 328ff03dc53SRichard Tran Mills PetscFunctionReturn(0); 329ff03dc53SRichard Tran Mills } 330ff03dc53SRichard Tran Mills 331*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 332ff03dc53SRichard Tran Mills #undef __FUNCT__ 333df555b71SRichard Tran Mills #define __FUNCT__ "MatMultAdd_SeqAIJMKL_SpMV2" 334df555b71SRichard Tran Mills PetscErrorCode MatMultAdd_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy,Vec zz) 335df555b71SRichard Tran Mills { 336df555b71SRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 337df555b71SRichard Tran Mills Mat_SeqAIJMKL *aijmkl=(Mat_SeqAIJMKL*)A->spptr; 338df555b71SRichard Tran Mills const PetscScalar *x; 339df555b71SRichard Tran Mills PetscScalar *y,*z; 340df555b71SRichard Tran Mills const MatScalar *aa; 341df555b71SRichard Tran Mills PetscErrorCode ierr; 342df555b71SRichard Tran Mills PetscInt m=A->rmap->n; 343df555b71SRichard Tran Mills const PetscInt *aj,*ai; 344df555b71SRichard Tran Mills PetscInt i; 345df555b71SRichard Tran Mills 346df555b71SRichard Tran Mills /* Variables not in MatMultAdd_SeqAIJ. */ 347df555b71SRichard Tran Mills sparse_status_t stat = SPARSE_STATUS_SUCCESS; 348df555b71SRichard Tran Mills 349df555b71SRichard Tran Mills PetscFunctionBegin; 350df555b71SRichard Tran Mills 351df555b71SRichard Tran Mills #ifdef DEBUG 352df555b71SRichard Tran Mills printf("DEBUG: In MatMultAdd_SeqAIJMKL_SpMV2\n"); 353df555b71SRichard Tran Mills #endif 354df555b71SRichard Tran Mills 355df555b71SRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 356df555b71SRichard Tran Mills ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 357df555b71SRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 358df555b71SRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 359df555b71SRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 360df555b71SRichard Tran Mills 361df555b71SRichard Tran Mills /* Call MKL sparse BLAS routine to do the MatMult. */ 362df555b71SRichard Tran Mills if (zz == yy) { 363df555b71SRichard 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, 364df555b71SRichard Tran Mills * with alpha and beta both set to 1.0. */ 365df555b71SRichard Tran Mills stat = mkl_sparse_x_mv(SPARSE_OPERATION_NON_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,1.0,y); 366df555b71SRichard Tran Mills } else { 367df555b71SRichard 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 368df555b71SRichard Tran Mills * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */ 369df555b71SRichard Tran Mills stat = mkl_sparse_x_mv(SPARSE_OPERATION_NON_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y); 370df555b71SRichard Tran Mills for (i=0; i<m; i++) { 371df555b71SRichard Tran Mills z[i] += y[i]; 372df555b71SRichard Tran Mills } 373df555b71SRichard Tran Mills } 374df555b71SRichard Tran Mills 375df555b71SRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr); 376df555b71SRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 377df555b71SRichard Tran Mills ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 378df555b71SRichard Tran Mills if (stat != SPARSE_STATUS_SUCCESS) { 379df555b71SRichard Tran Mills PetscFunctionReturn(PETSC_ERR_LIB); 380df555b71SRichard Tran Mills } 381df555b71SRichard Tran Mills PetscFunctionReturn(0); 382df555b71SRichard Tran Mills } 383*d995685eSRichard Tran Mills #endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */ 384df555b71SRichard Tran Mills 385df555b71SRichard Tran Mills #undef __FUNCT__ 386ff03dc53SRichard Tran Mills #define __FUNCT__ "MatMultTransposeAdd_SeqAIJMKL" 387ff03dc53SRichard Tran Mills PetscErrorCode MatMultTransposeAdd_SeqAIJMKL(Mat A,Vec xx,Vec yy,Vec zz) 388ff03dc53SRichard Tran Mills { 389ff03dc53SRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 390ff03dc53SRichard Tran Mills const PetscScalar *x; 391ff03dc53SRichard Tran Mills PetscScalar *y,*z; 392ff03dc53SRichard Tran Mills const MatScalar *aa; 393ff03dc53SRichard Tran Mills PetscErrorCode ierr; 394ff03dc53SRichard Tran Mills PetscInt m=A->rmap->n; 395ff03dc53SRichard Tran Mills const PetscInt *aj,*ai; 396ff03dc53SRichard Tran Mills PetscInt i; 397ff03dc53SRichard Tran Mills 398ff03dc53SRichard Tran Mills /* Variables not in MatMultTransposeAdd_SeqAIJ. */ 399ff03dc53SRichard Tran Mills char transa = 't'; /* Used to indicate to MKL that we are computing the transpose product. */ 400a84739b8SRichard Tran Mills PetscScalar alpha = 1.0; 401a84739b8SRichard Tran Mills PetscScalar beta = 1.0; 402a84739b8SRichard Tran Mills char matdescra[6]; 4034a2a386eSRichard Tran Mills 4044a2a386eSRichard Tran Mills PetscFunctionBegin; 405a84739b8SRichard Tran Mills matdescra[0] = 'g'; /* Indicates to MKL that we using a general CSR matrix. */ 406a84739b8SRichard Tran Mills matdescra[3] = 'c'; /* Indicates to MKL that we use C-style (0-based) indexing. */ 407a84739b8SRichard Tran Mills 4084a2a386eSRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 4094a2a386eSRichard Tran Mills ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 4104a2a386eSRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 4114a2a386eSRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 4124a2a386eSRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 4134a2a386eSRichard Tran Mills 4144a2a386eSRichard Tran Mills /* Call MKL sparse BLAS routine to do the MatMult. */ 415a84739b8SRichard Tran Mills if (zz == yy) { 416a84739b8SRichard 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. */ 417a84739b8SRichard Tran Mills mkl_xcsrmv(&transa,&m,&m,&alpha,matdescra,aa,aj,ai,ai+1,x,&beta,y); 418a84739b8SRichard Tran Mills } else { 419a84739b8SRichard Tran Mills /* zz and yy are different vectors, so we call mkl_cspblas_xcsrgemv(), which calculates y = A*x, and then 420a84739b8SRichard Tran Mills * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */ 4214a2a386eSRichard Tran Mills mkl_cspblas_xcsrgemv(&transa,&m,aa,ai,aj,x,z); 4224a2a386eSRichard Tran Mills for (i=0; i<m; i++) { 4234a2a386eSRichard Tran Mills z[i] += y[i]; 4244a2a386eSRichard Tran Mills } 425a84739b8SRichard Tran Mills } 4264a2a386eSRichard Tran Mills 4274a2a386eSRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr); 4284a2a386eSRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 4294a2a386eSRichard Tran Mills ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 4304a2a386eSRichard Tran Mills PetscFunctionReturn(0); 4314a2a386eSRichard Tran Mills } 4324a2a386eSRichard Tran Mills 433*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 434df555b71SRichard Tran Mills #undef __FUNCT__ 435df555b71SRichard Tran Mills #define __FUNCT__ "MatMultTransposeAdd_SeqAIJMKL_SpMV2" 436df555b71SRichard Tran Mills PetscErrorCode MatMultTransposeAdd_SeqAIJMKL_SpMV2(Mat A,Vec xx,Vec yy,Vec zz) 437df555b71SRichard Tran Mills { 438df555b71SRichard Tran Mills Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; 439df555b71SRichard Tran Mills Mat_SeqAIJMKL *aijmkl=(Mat_SeqAIJMKL*)A->spptr; 440df555b71SRichard Tran Mills const PetscScalar *x; 441df555b71SRichard Tran Mills PetscScalar *y,*z; 442df555b71SRichard Tran Mills const MatScalar *aa; 443df555b71SRichard Tran Mills PetscErrorCode ierr; 444df555b71SRichard Tran Mills PetscInt m=A->rmap->n; 445df555b71SRichard Tran Mills const PetscInt *aj,*ai; 446df555b71SRichard Tran Mills PetscInt i; 447df555b71SRichard Tran Mills 448df555b71SRichard Tran Mills /* Variables not in MatMultTransposeAdd_SeqAIJ. */ 449df555b71SRichard Tran Mills sparse_status_t stat = SPARSE_STATUS_SUCCESS; 450df555b71SRichard Tran Mills 451df555b71SRichard Tran Mills PetscFunctionBegin; 452df555b71SRichard Tran Mills 453df555b71SRichard Tran Mills #ifdef DEBUG 454df555b71SRichard Tran Mills printf("DEBUG: In MatMultTransposeAdd_SeqAIJMKL_SpMV2\n"); 455df555b71SRichard Tran Mills #endif 456df555b71SRichard Tran Mills 457df555b71SRichard Tran Mills ierr = VecGetArrayRead(xx,&x);CHKERRQ(ierr); 458df555b71SRichard Tran Mills ierr = VecGetArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 459df555b71SRichard Tran Mills aj = a->j; /* aj[k] gives column index for element aa[k]. */ 460df555b71SRichard Tran Mills aa = a->a; /* Nonzero elements stored row-by-row. */ 461df555b71SRichard Tran Mills ai = a->i; /* ai[k] is the position in aa and aj where row k starts. */ 462df555b71SRichard Tran Mills 463df555b71SRichard Tran Mills /* Call MKL sparse BLAS routine to do the MatMult. */ 464df555b71SRichard Tran Mills if (zz == yy) { 465df555b71SRichard 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, 466df555b71SRichard Tran Mills * with alpha and beta both set to 1.0. */ 467df555b71SRichard Tran Mills stat = mkl_sparse_x_mv(SPARSE_OPERATION_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,1.0,y); 468df555b71SRichard Tran Mills } else { 469df555b71SRichard 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 470df555b71SRichard Tran Mills * we add the contents of vector yy to the result; MKL sparse BLAS does not have a MatMultAdd equivalent. */ 471df555b71SRichard Tran Mills stat = mkl_sparse_x_mv(SPARSE_OPERATION_TRANSPOSE,1.0,aijmkl->csrA,aijmkl->descr,x,0.0,y); 472df555b71SRichard Tran Mills for (i=0; i<m; i++) { 473df555b71SRichard Tran Mills z[i] += y[i]; 474df555b71SRichard Tran Mills } 475df555b71SRichard Tran Mills } 476df555b71SRichard Tran Mills 477df555b71SRichard Tran Mills ierr = PetscLogFlops(2.0*a->nz);CHKERRQ(ierr); 478df555b71SRichard Tran Mills ierr = VecRestoreArrayRead(xx,&x);CHKERRQ(ierr); 479df555b71SRichard Tran Mills ierr = VecRestoreArrayPair(yy,zz,&y,&z);CHKERRQ(ierr); 480df555b71SRichard Tran Mills if (stat != SPARSE_STATUS_SUCCESS) { 481df555b71SRichard Tran Mills PetscFunctionReturn(PETSC_ERR_LIB); 482df555b71SRichard Tran Mills } 483df555b71SRichard Tran Mills PetscFunctionReturn(0); 484df555b71SRichard Tran Mills } 485*d995685eSRichard Tran Mills #endif /* PETSC_HAVE_MKL_SPARSE_OPTIMIZE */ 486df555b71SRichard Tran Mills 487df555b71SRichard Tran Mills 4884a2a386eSRichard Tran Mills /* MatConvert_SeqAIJ_SeqAIJMKL converts a SeqAIJ matrix into a 4894a2a386eSRichard Tran Mills * SeqAIJMKL matrix. This routine is called by the MatCreate_SeqMKLAIJ() 4904a2a386eSRichard Tran Mills * routine, but can also be used to convert an assembled SeqAIJ matrix 4914a2a386eSRichard Tran Mills * into a SeqAIJMKL one. */ 4924a2a386eSRichard Tran Mills #undef __FUNCT__ 4934a2a386eSRichard Tran Mills #define __FUNCT__ "MatConvert_SeqAIJ_SeqAIJMKL" 4944a2a386eSRichard Tran Mills PETSC_INTERN PetscErrorCode MatConvert_SeqAIJ_SeqAIJMKL(Mat A,MatType type,MatReuse reuse,Mat *newmat) 4954a2a386eSRichard Tran Mills { 4964a2a386eSRichard Tran Mills PetscErrorCode ierr; 4974a2a386eSRichard Tran Mills Mat B = *newmat; 4984a2a386eSRichard Tran Mills Mat_SeqAIJMKL *aijmkl; 499c9d46305SRichard Tran Mills PetscBool set; 5004a2a386eSRichard Tran Mills 5014a2a386eSRichard Tran Mills PetscFunctionBegin; 5024a2a386eSRichard Tran Mills if (reuse == MAT_INITIAL_MATRIX) { 5034a2a386eSRichard Tran Mills ierr = MatDuplicate(A,MAT_COPY_VALUES,&B);CHKERRQ(ierr); 5044a2a386eSRichard Tran Mills } 5054a2a386eSRichard Tran Mills 5064a2a386eSRichard Tran Mills ierr = PetscNewLog(B,&aijmkl);CHKERRQ(ierr); 5074a2a386eSRichard Tran Mills B->spptr = (void*) aijmkl; 5084a2a386eSRichard Tran Mills 509df555b71SRichard Tran Mills /* Set function pointers for methods that we inherit from AIJ but override. 510df555b71SRichard Tran Mills * Currently the transposed operations are not being set because I encounter memory corruption 511df555b71SRichard Tran Mills * when these are enabled. Need to look at this with Valgrind or similar. --RTM */ 5124a2a386eSRichard Tran Mills B->ops->duplicate = MatDuplicate_SeqAIJMKL; 5134a2a386eSRichard Tran Mills B->ops->assemblyend = MatAssemblyEnd_SeqAIJMKL; 5144a2a386eSRichard Tran Mills B->ops->destroy = MatDestroy_SeqAIJMKL; 515c9d46305SRichard Tran Mills 516c9d46305SRichard Tran Mills /* Parse command line options. */ 517*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 518*d995685eSRichard Tran Mills aijmkl->no_SpMV2 = PETSC_FALSE; /* Default to using the SpMV2 routines if our MKL supports them. */ 519*d995685eSRichard Tran Mills #elif 520*d995685eSRichard Tran Mills aijmkl->no_SpMV2 = PETSC_TRUE; 521*d995685eSRichard Tran Mills #endif 522c9d46305SRichard Tran Mills ierr = PetscOptionsBegin(PetscObjectComm((PetscObject)A),((PetscObject)A)->prefix,"AIJMKL Options","Mat");CHKERRQ(ierr); 523c9d46305SRichard Tran Mills ierr = PetscOptionsBool("-mat_aijmkl_no_spmv2","NoSPMV2","None",(PetscBool)aijmkl->no_SpMV2,(PetscBool*)&aijmkl->no_SpMV2,&set);CHKERRQ(ierr); 524c9d46305SRichard Tran Mills ierr = PetscOptionsEnd();CHKERRQ(ierr); 525*d995685eSRichard Tran Mills #ifndef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 526*d995685eSRichard Tran Mills if(!aijmkl->no_SpMV2) { 527*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"); 528*d995685eSRichard Tran Mills aijmkl->no_SpMV2 = PETSC_TRUE; 529*d995685eSRichard Tran Mills } 530*d995685eSRichard Tran Mills #endif 531c9d46305SRichard Tran Mills 532c9d46305SRichard Tran Mills if(!aijmkl->no_SpMV2) { 533*d995685eSRichard Tran Mills #ifdef PETSC_HAVE_MKL_SPARSE_OPTIMIZE 534df555b71SRichard Tran Mills B->ops->mult = MatMult_SeqAIJMKL_SpMV2; 535df555b71SRichard Tran Mills /* B->ops->multtranspose = MatMultTranspose_SeqAIJMKL_SpMV2; */ 536df555b71SRichard Tran Mills B->ops->multadd = MatMultAdd_SeqAIJMKL_SpMV2; 537df555b71SRichard Tran Mills /* B->ops->multtransposeadd = MatMultTransposeAdd_SeqAIJMKL_SpMV2; */ 538*d995685eSRichard Tran Mills #endif 539c9d46305SRichard Tran Mills } else { 5404a2a386eSRichard Tran Mills B->ops->mult = MatMult_SeqAIJMKL; 541c9d46305SRichard Tran Mills /* B->ops->multtranspose = MatMultTranspose_SeqAIJMKL; */ 5424a2a386eSRichard Tran Mills B->ops->multadd = MatMultAdd_SeqAIJMKL; 543c9d46305SRichard Tran Mills /* B->ops->multtransposeadd = MatMultTransposeAdd_SeqAIJMKL; */ 544c9d46305SRichard Tran Mills } 5454a2a386eSRichard Tran Mills 5464a2a386eSRichard Tran Mills ierr = PetscObjectComposeFunction((PetscObject)B,"MatConvert_seqaijmkl_seqaij_C",MatConvert_SeqAIJMKL_SeqAIJ);CHKERRQ(ierr); 5474a2a386eSRichard Tran Mills 5484a2a386eSRichard Tran Mills ierr = PetscObjectChangeTypeName((PetscObject)B,MATSEQAIJMKL);CHKERRQ(ierr); 5494a2a386eSRichard Tran Mills *newmat = B; 5504a2a386eSRichard Tran Mills PetscFunctionReturn(0); 5514a2a386eSRichard Tran Mills } 5524a2a386eSRichard Tran Mills 5534a2a386eSRichard Tran Mills #undef __FUNCT__ 5544a2a386eSRichard Tran Mills #define __FUNCT__ "MatCreateSeqAIJMKL" 5554a2a386eSRichard Tran Mills /*@C 5564a2a386eSRichard Tran Mills MatCreateSeqAIJMKL - Creates a sparse matrix of type SEQAIJMKL. 5574a2a386eSRichard Tran Mills This type inherits from AIJ and is largely identical, but uses sparse BLAS 5584a2a386eSRichard Tran Mills routines from Intel MKL whenever possible. 5594a2a386eSRichard Tran Mills Collective on MPI_Comm 5604a2a386eSRichard Tran Mills 5614a2a386eSRichard Tran Mills Input Parameters: 5624a2a386eSRichard Tran Mills + comm - MPI communicator, set to PETSC_COMM_SELF 5634a2a386eSRichard Tran Mills . m - number of rows 5644a2a386eSRichard Tran Mills . n - number of columns 5654a2a386eSRichard Tran Mills . nz - number of nonzeros per row (same for all rows) 5664a2a386eSRichard Tran Mills - nnz - array containing the number of nonzeros in the various rows 5674a2a386eSRichard Tran Mills (possibly different for each row) or NULL 5684a2a386eSRichard Tran Mills 5694a2a386eSRichard Tran Mills Output Parameter: 5704a2a386eSRichard Tran Mills . A - the matrix 5714a2a386eSRichard Tran Mills 5724a2a386eSRichard Tran Mills Notes: 5734a2a386eSRichard Tran Mills If nnz is given then nz is ignored 5744a2a386eSRichard Tran Mills 5754a2a386eSRichard Tran Mills Level: intermediate 5764a2a386eSRichard Tran Mills 5774a2a386eSRichard Tran Mills .keywords: matrix, cray, sparse, parallel 5784a2a386eSRichard Tran Mills 5794a2a386eSRichard Tran Mills .seealso: MatCreate(), MatCreateMPIAIJMKL(), MatSetValues() 5804a2a386eSRichard Tran Mills @*/ 5814a2a386eSRichard Tran Mills PetscErrorCode MatCreateSeqAIJMKL(MPI_Comm comm,PetscInt m,PetscInt n,PetscInt nz,const PetscInt nnz[],Mat *A) 5824a2a386eSRichard Tran Mills { 5834a2a386eSRichard Tran Mills PetscErrorCode ierr; 5844a2a386eSRichard Tran Mills 5854a2a386eSRichard Tran Mills PetscFunctionBegin; 5864a2a386eSRichard Tran Mills ierr = MatCreate(comm,A);CHKERRQ(ierr); 5874a2a386eSRichard Tran Mills ierr = MatSetSizes(*A,m,n,m,n);CHKERRQ(ierr); 5884a2a386eSRichard Tran Mills ierr = MatSetType(*A,MATSEQAIJMKL);CHKERRQ(ierr); 5894a2a386eSRichard Tran Mills ierr = MatSeqAIJSetPreallocation_SeqAIJ(*A,nz,nnz);CHKERRQ(ierr); 5904a2a386eSRichard Tran Mills PetscFunctionReturn(0); 5914a2a386eSRichard Tran Mills } 5924a2a386eSRichard Tran Mills 5934a2a386eSRichard Tran Mills #undef __FUNCT__ 5944a2a386eSRichard Tran Mills #define __FUNCT__ "MatCreate_SeqAIJMKL" 5954a2a386eSRichard Tran Mills PETSC_EXTERN PetscErrorCode MatCreate_SeqAIJMKL(Mat A) 5964a2a386eSRichard Tran Mills { 5974a2a386eSRichard Tran Mills PetscErrorCode ierr; 5984a2a386eSRichard Tran Mills 5994a2a386eSRichard Tran Mills PetscFunctionBegin; 6004a2a386eSRichard Tran Mills ierr = MatSetType(A,MATSEQAIJ);CHKERRQ(ierr); 6014a2a386eSRichard Tran Mills ierr = MatConvert_SeqAIJ_SeqAIJMKL(A,MATSEQAIJMKL,MAT_INPLACE_MATRIX,&A);CHKERRQ(ierr); 6024a2a386eSRichard Tran Mills PetscFunctionReturn(0); 6034a2a386eSRichard Tran Mills } 604