#include <../src/mat/impls/aij/seq/aij.h> /*I "petscmat.h" I*/ #include <../src/mat/impls/sbaij/seq/sbaij.h> #include <../src/mat/impls/dense/seq/dense.h> #if defined(PETSC_HAVE_MKL_INTEL_ILP64) #define MKL_ILP64 #endif #include PETSC_EXTERN void PetscSetMKL_PARDISOThreads(int); /* * Possible mkl_pardiso phases that controls the execution of the solver. * For more information check mkl_pardiso manual. */ #define JOB_ANALYSIS 11 #define JOB_ANALYSIS_NUMERICAL_FACTORIZATION 12 #define JOB_ANALYSIS_NUMERICAL_FACTORIZATION_SOLVE_ITERATIVE_REFINEMENT 13 #define JOB_NUMERICAL_FACTORIZATION 22 #define JOB_NUMERICAL_FACTORIZATION_SOLVE_ITERATIVE_REFINEMENT 23 #define JOB_SOLVE_ITERATIVE_REFINEMENT 33 #define JOB_SOLVE_FORWARD_SUBSTITUTION 331 #define JOB_SOLVE_DIAGONAL_SUBSTITUTION 332 #define JOB_SOLVE_BACKWARD_SUBSTITUTION 333 #define JOB_RELEASE_OF_LU_MEMORY 0 #define JOB_RELEASE_OF_ALL_MEMORY -1 #define IPARM_SIZE 64 #if defined(PETSC_USE_64BIT_INDICES) #if defined(PETSC_HAVE_MKL_INTEL_ILP64) #define INT_TYPE long long int #define MKL_PARDISO pardiso #define MKL_PARDISO_INIT pardisoinit #else /* this is the case where the MKL BLAS/LAPACK are 32 bit integers but the 64 bit integer version of of Pardiso code is used; hence the need for the 64 below*/ #define INT_TYPE long long int #define MKL_PARDISO pardiso_64 #define MKL_PARDISO_INIT pardiso_64init void pardiso_64init(void *pt, INT_TYPE *mtype, INT_TYPE iparm []) { int iparm_copy[IPARM_SIZE], mtype_copy, i; mtype_copy = *mtype; pardisoinit(pt, &mtype_copy, iparm_copy); for (i=0; idata; PetscInt bs = A->rmap->bs,i; PetscFunctionBegin; PetscCheck(sym,PetscObjectComm((PetscObject)A),PETSC_ERR_PLIB,"This should not happen"); *v = aa->a; if (bs == 1) { /* already in the correct format */ /* though PetscInt and INT_TYPE are of the same size since they are defined differently the Intel compiler requires a cast */ *r = (INT_TYPE*)aa->i; *c = (INT_TYPE*)aa->j; *nnz = (INT_TYPE)aa->nz; *free = PETSC_FALSE; } else if (reuse == MAT_INITIAL_MATRIX) { PetscInt m = A->rmap->n,nz = aa->nz; PetscInt *row,*col; PetscCall(PetscMalloc2(m+1,&row,nz,&col)); for (i=0; ii[i]+1; } for (i=0; ij[i]+1; } *r = (INT_TYPE*)row; *c = (INT_TYPE*)col; *nnz = (INT_TYPE)nz; *free = PETSC_TRUE; } PetscFunctionReturn(0); } PetscErrorCode MatMKLPardiso_Convert_seqbaij(Mat A,PetscBool sym,MatReuse reuse,PetscBool *free,INT_TYPE *nnz,INT_TYPE **r,INT_TYPE **c,PetscScalar **v) { Mat_SeqBAIJ *aa = (Mat_SeqBAIJ*)A->data; PetscInt bs = A->rmap->bs,i; PetscFunctionBegin; if (!sym) { *v = aa->a; if (bs == 1) { /* already in the correct format */ /* though PetscInt and INT_TYPE are of the same size since they are defined differently the Intel compiler requires a cast */ *r = (INT_TYPE*)aa->i; *c = (INT_TYPE*)aa->j; *nnz = (INT_TYPE)aa->nz; *free = PETSC_FALSE; PetscFunctionReturn(0); } else if (reuse == MAT_INITIAL_MATRIX) { PetscInt m = A->rmap->n,nz = aa->nz; PetscInt *row,*col; PetscCall(PetscMalloc2(m+1,&row,nz,&col)); for (i=0; ii[i]+1; } for (i=0; ij[i]+1; } *r = (INT_TYPE*)row; *c = (INT_TYPE*)col; *nnz = (INT_TYPE)nz; } *free = PETSC_TRUE; } else { SETERRQ(PetscObjectComm((PetscObject)A),PETSC_ERR_PLIB,"This should not happen"); } PetscFunctionReturn(0); } PetscErrorCode MatMKLPardiso_Convert_seqaij(Mat A,PetscBool sym,MatReuse reuse,PetscBool *free,INT_TYPE *nnz,INT_TYPE **r,INT_TYPE **c,PetscScalar **v) { Mat_SeqAIJ *aa = (Mat_SeqAIJ*)A->data; PetscScalar *aav; PetscFunctionBegin; PetscCall(MatSeqAIJGetArrayRead(A,(const PetscScalar**)&aav)); if (!sym) { /* already in the correct format */ *v = aav; *r = (INT_TYPE*)aa->i; *c = (INT_TYPE*)aa->j; *nnz = (INT_TYPE)aa->nz; *free = PETSC_FALSE; } else if (reuse == MAT_INITIAL_MATRIX) { /* need to get the triangular part */ PetscScalar *vals,*vv; PetscInt *row,*col,*jj; PetscInt m = A->rmap->n,nz,i; nz = 0; for (i=0; ii[i+1] - aa->diag[i]; PetscCall(PetscMalloc2(m+1,&row,nz,&col)); PetscCall(PetscMalloc1(nz,&vals)); jj = col; vv = vals; row[0] = 0; for (i=0; ij + aa->diag[i]; PetscScalar *av = aav + aa->diag[i]; PetscInt rl = aa->i[i+1] - aa->diag[i],j; for (j=0; jrmap->n,i; vv = *v; for (i=0; idiag[i]; PetscInt rl = aa->i[i+1] - aa->diag[i],j; for (j=0; jdata; Mat S,Xmat,Bmat; MatFactorSchurStatus schurstatus; PetscFunctionBegin; PetscCall(MatFactorGetSchurComplement(F,&S,&schurstatus)); PetscCheck(X != B || schurstatus != MAT_FACTOR_SCHUR_INVERTED,PETSC_COMM_SELF,PETSC_ERR_SUP,"X and B cannot point to the same address"); PetscCall(MatCreateSeqDense(PETSC_COMM_SELF,mpardiso->schur_size,mpardiso->nrhs,B,&Bmat)); PetscCall(MatCreateSeqDense(PETSC_COMM_SELF,mpardiso->schur_size,mpardiso->nrhs,X,&Xmat)); PetscCall(MatSetType(Bmat,((PetscObject)S)->type_name)); PetscCall(MatSetType(Xmat,((PetscObject)S)->type_name)); #if defined(PETSC_HAVE_VIENNACL) || defined(PETSC_HAVE_CUDA) PetscCall(MatBindToCPU(Xmat,S->boundtocpu)); PetscCall(MatBindToCPU(Bmat,S->boundtocpu)); #endif #if defined(PETSC_USE_COMPLEX) PetscCheck(mpardiso->iparm[12-1] != 1,PetscObjectComm((PetscObject)F),PETSC_ERR_SUP,"Hermitian solve not implemented yet"); #endif switch (schurstatus) { case MAT_FACTOR_SCHUR_FACTORED: if (!mpardiso->iparm[12-1]) { PetscCall(MatMatSolve(S,Bmat,Xmat)); } else { /* transpose solve */ PetscCall(MatMatSolveTranspose(S,Bmat,Xmat)); } break; case MAT_FACTOR_SCHUR_INVERTED: PetscCall(MatProductCreateWithMat(S,Bmat,NULL,Xmat)); if (!mpardiso->iparm[12-1]) { PetscCall(MatProductSetType(Xmat,MATPRODUCT_AB)); } else { /* transpose solve */ PetscCall(MatProductSetType(Xmat,MATPRODUCT_AtB)); } PetscCall(MatProductSetFromOptions(Xmat)); PetscCall(MatProductSymbolic(Xmat)); PetscCall(MatProductNumeric(Xmat)); PetscCall(MatProductClear(Xmat)); break; default: SETERRQ(PetscObjectComm((PetscObject)F),PETSC_ERR_SUP,"Unhandled MatFactorSchurStatus %" PetscInt_FMT,F->schur_status); break; } PetscCall(MatFactorRestoreSchurComplement(F,&S,schurstatus)); PetscCall(MatDestroy(&Bmat)); PetscCall(MatDestroy(&Xmat)); PetscFunctionReturn(0); } PetscErrorCode MatFactorSetSchurIS_MKL_PARDISO(Mat F, IS is) { Mat_MKL_PARDISO *mpardiso = (Mat_MKL_PARDISO*)F->data; const PetscScalar *arr; const PetscInt *idxs; PetscInt size,i; PetscMPIInt csize; PetscBool sorted; PetscFunctionBegin; PetscCallMPI(MPI_Comm_size(PetscObjectComm((PetscObject)F),&csize)); PetscCheck(csize <= 1,PETSC_COMM_SELF,PETSC_ERR_SUP,"MKL_PARDISO parallel Schur complements not yet supported from PETSc"); PetscCall(ISSorted(is,&sorted)); PetscCheck(sorted,PETSC_COMM_SELF,PETSC_ERR_SUP,"IS for MKL_PARDISO Schur complements needs to be sorted"); PetscCall(ISGetLocalSize(is,&size)); PetscCall(PetscFree(mpardiso->schur_work)); PetscCall(PetscBLASIntCast(PetscMax(mpardiso->n,2*size),&mpardiso->schur_work_size)); PetscCall(PetscMalloc1(mpardiso->schur_work_size,&mpardiso->schur_work)); PetscCall(MatDestroy(&F->schur)); PetscCall(MatCreateSeqDense(PETSC_COMM_SELF,size,size,NULL,&F->schur)); PetscCall(MatDenseGetArrayRead(F->schur,&arr)); mpardiso->schur = (PetscScalar*)arr; mpardiso->schur_size = size; PetscCall(MatDenseRestoreArrayRead(F->schur,&arr)); if (mpardiso->mtype == 2) { PetscCall(MatSetOption(F->schur,MAT_SPD,PETSC_TRUE)); } PetscCall(PetscFree(mpardiso->schur_idxs)); PetscCall(PetscMalloc1(size,&mpardiso->schur_idxs)); PetscCall(PetscArrayzero(mpardiso->perm,mpardiso->n)); PetscCall(ISGetIndices(is,&idxs)); PetscCall(PetscArraycpy(mpardiso->schur_idxs,idxs,size)); for (i=0;iperm[idxs[i]] = 1; PetscCall(ISRestoreIndices(is,&idxs)); if (size) { /* turn on Schur switch if the set of indices is not empty */ mpardiso->iparm[36-1] = 2; } PetscFunctionReturn(0); } PetscErrorCode MatDestroy_MKL_PARDISO(Mat A) { Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)A->data; PetscFunctionBegin; if (mat_mkl_pardiso->CleanUp) { mat_mkl_pardiso->phase = JOB_RELEASE_OF_ALL_MEMORY; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, NULL, NULL, NULL, NULL, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, NULL, NULL, &mat_mkl_pardiso->err); } PetscCall(PetscFree(mat_mkl_pardiso->perm)); PetscCall(PetscFree(mat_mkl_pardiso->schur_work)); PetscCall(PetscFree(mat_mkl_pardiso->schur_idxs)); if (mat_mkl_pardiso->freeaij) { PetscCall(PetscFree2(mat_mkl_pardiso->ia,mat_mkl_pardiso->ja)); if (mat_mkl_pardiso->iparm[34] == 1) { PetscCall(PetscFree(mat_mkl_pardiso->a)); } } PetscCall(PetscFree(A->data)); /* clear composed functions */ PetscCall(PetscObjectComposeFunction((PetscObject)A,"MatFactorGetSolverType_C",NULL)); PetscCall(PetscObjectComposeFunction((PetscObject)A,"MatFactorSetSchurIS_C",NULL)); PetscCall(PetscObjectComposeFunction((PetscObject)A,"MatMkl_PardisoSetCntl_C",NULL)); PetscFunctionReturn(0); } static PetscErrorCode MatMKLPardisoScatterSchur_Private(Mat_MKL_PARDISO *mpardiso, PetscScalar *whole, PetscScalar *schur, PetscBool reduce) { PetscFunctionBegin; if (reduce) { /* data given for the whole matrix */ PetscInt i,m=0,p=0; for (i=0;inrhs;i++) { PetscInt j; for (j=0;jschur_size;j++) { schur[p+j] = whole[m+mpardiso->schur_idxs[j]]; } m += mpardiso->n; p += mpardiso->schur_size; } } else { /* from Schur to whole */ PetscInt i,m=0,p=0; for (i=0;inrhs;i++) { PetscInt j; for (j=0;jschur_size;j++) { whole[m+mpardiso->schur_idxs[j]] = schur[p+j]; } m += mpardiso->n; p += mpardiso->schur_size; } } PetscFunctionReturn(0); } PetscErrorCode MatSolve_MKL_PARDISO(Mat A,Vec b,Vec x) { Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)A->data; PetscScalar *xarray; const PetscScalar *barray; PetscFunctionBegin; mat_mkl_pardiso->nrhs = 1; PetscCall(VecGetArrayWrite(x,&xarray)); PetscCall(VecGetArrayRead(b,&barray)); if (!mat_mkl_pardiso->schur) mat_mkl_pardiso->phase = JOB_SOLVE_ITERATIVE_REFINEMENT; else mat_mkl_pardiso->phase = JOB_SOLVE_FORWARD_SUBSTITUTION; if (barray == xarray) { /* if the two vectors share the same memory */ PetscScalar *work; if (!mat_mkl_pardiso->schur_work) { PetscCall(PetscMalloc1(mat_mkl_pardiso->n,&work)); } else { work = mat_mkl_pardiso->schur_work; } mat_mkl_pardiso->iparm[6-1] = 1; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, NULL, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, (void*)xarray, (void*)work, &mat_mkl_pardiso->err); if (!mat_mkl_pardiso->schur_work) { PetscCall(PetscFree(work)); } } else { mat_mkl_pardiso->iparm[6-1] = 0; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, mat_mkl_pardiso->perm, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, (void*)barray, (void*)xarray, &mat_mkl_pardiso->err); } PetscCall(VecRestoreArrayRead(b,&barray)); PetscCheck(mat_mkl_pardiso->err >= 0,PETSC_COMM_SELF,PETSC_ERR_LIB,"Error reported by MKL_PARDISO: err=%d. Please check manual",mat_mkl_pardiso->err); if (mat_mkl_pardiso->schur) { /* solve Schur complement and expand solution */ if (!mat_mkl_pardiso->solve_interior) { PetscInt shift = mat_mkl_pardiso->schur_size; PetscCall(MatFactorFactorizeSchurComplement(A)); /* if inverted, uses BLAS *MM subroutines, otherwise LAPACK *TRS */ if (A->schur_status != MAT_FACTOR_SCHUR_INVERTED) shift = 0; /* solve Schur complement */ PetscCall(MatMKLPardisoScatterSchur_Private(mat_mkl_pardiso,xarray,mat_mkl_pardiso->schur_work,PETSC_TRUE)); PetscCall(MatMKLPardisoSolveSchur_Private(A,mat_mkl_pardiso->schur_work,mat_mkl_pardiso->schur_work+shift)); PetscCall(MatMKLPardisoScatterSchur_Private(mat_mkl_pardiso,xarray,mat_mkl_pardiso->schur_work+shift,PETSC_FALSE)); } else { /* if we are solving for the interior problem, any value in barray[schur] forward-substituted to xarray[schur] will be neglected */ PetscInt i; for (i=0;ischur_size;i++) { xarray[mat_mkl_pardiso->schur_idxs[i]] = 0.; } } /* expansion phase */ mat_mkl_pardiso->iparm[6-1] = 1; mat_mkl_pardiso->phase = JOB_SOLVE_BACKWARD_SUBSTITUTION; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, mat_mkl_pardiso->perm, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, (void*)xarray, (void*)mat_mkl_pardiso->schur_work, /* according to the specs, the solution vector is always used */ &mat_mkl_pardiso->err); PetscCheck(mat_mkl_pardiso->err >= 0,PETSC_COMM_SELF,PETSC_ERR_LIB,"Error reported by MKL_PARDISO: err=%d. Please check manual",mat_mkl_pardiso->err); mat_mkl_pardiso->iparm[6-1] = 0; } PetscCall(VecRestoreArrayWrite(x,&xarray)); mat_mkl_pardiso->CleanUp = PETSC_TRUE; PetscFunctionReturn(0); } PetscErrorCode MatSolveTranspose_MKL_PARDISO(Mat A,Vec b,Vec x) { Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)A->data; PetscInt oiparm12; PetscFunctionBegin; oiparm12 = mat_mkl_pardiso->iparm[12 - 1]; mat_mkl_pardiso->iparm[12 - 1] = 2; PetscCall(MatSolve_MKL_PARDISO(A,b,x)); mat_mkl_pardiso->iparm[12 - 1] = oiparm12; PetscFunctionReturn(0); } PetscErrorCode MatMatSolve_MKL_PARDISO(Mat A,Mat B,Mat X) { Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)(A)->data; const PetscScalar *barray; PetscScalar *xarray; PetscBool flg; PetscFunctionBegin; PetscCall(PetscObjectBaseTypeCompare((PetscObject)B,MATSEQDENSE,&flg)); PetscCheck(flg,PetscObjectComm((PetscObject)A),PETSC_ERR_ARG_WRONG,"Matrix B must be MATSEQDENSE matrix"); if (X != B) { PetscCall(PetscObjectBaseTypeCompare((PetscObject)X,MATSEQDENSE,&flg)); PetscCheck(flg,PetscObjectComm((PetscObject)A),PETSC_ERR_ARG_WRONG,"Matrix X must be MATSEQDENSE matrix"); } PetscCall(MatGetSize(B,NULL,(PetscInt*)&mat_mkl_pardiso->nrhs)); if (mat_mkl_pardiso->nrhs > 0) { PetscCall(MatDenseGetArrayRead(B,&barray)); PetscCall(MatDenseGetArrayWrite(X,&xarray)); PetscCheck(barray != xarray,PETSC_COMM_SELF,PETSC_ERR_SUP,"B and X cannot share the same memory location"); if (!mat_mkl_pardiso->schur) mat_mkl_pardiso->phase = JOB_SOLVE_ITERATIVE_REFINEMENT; else mat_mkl_pardiso->phase = JOB_SOLVE_FORWARD_SUBSTITUTION; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, mat_mkl_pardiso->perm, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, (void*)barray, (void*)xarray, &mat_mkl_pardiso->err); PetscCheck(mat_mkl_pardiso->err >= 0,PETSC_COMM_SELF,PETSC_ERR_LIB,"Error reported by MKL_PARDISO: err=%d. Please check manual",mat_mkl_pardiso->err); PetscCall(MatDenseRestoreArrayRead(B,&barray)); if (mat_mkl_pardiso->schur) { /* solve Schur complement and expand solution */ PetscScalar *o_schur_work = NULL; /* solve Schur complement */ if (!mat_mkl_pardiso->solve_interior) { PetscInt shift = mat_mkl_pardiso->schur_size*mat_mkl_pardiso->nrhs,scale; PetscInt mem = mat_mkl_pardiso->n*mat_mkl_pardiso->nrhs; PetscCall(MatFactorFactorizeSchurComplement(A)); /* allocate extra memory if it is needed */ scale = 1; if (A->schur_status == MAT_FACTOR_SCHUR_INVERTED) scale = 2; mem *= scale; if (mem > mat_mkl_pardiso->schur_work_size) { o_schur_work = mat_mkl_pardiso->schur_work; PetscCall(PetscMalloc1(mem,&mat_mkl_pardiso->schur_work)); } /* if inverted, uses BLAS *MM subroutines, otherwise LAPACK *TRS */ if (A->schur_status != MAT_FACTOR_SCHUR_INVERTED) shift = 0; PetscCall(MatMKLPardisoScatterSchur_Private(mat_mkl_pardiso,xarray,mat_mkl_pardiso->schur_work,PETSC_TRUE)); PetscCall(MatMKLPardisoSolveSchur_Private(A,mat_mkl_pardiso->schur_work,mat_mkl_pardiso->schur_work+shift)); PetscCall(MatMKLPardisoScatterSchur_Private(mat_mkl_pardiso,xarray,mat_mkl_pardiso->schur_work+shift,PETSC_FALSE)); } else { /* if we are solving for the interior problem, any value in barray[schur,n] forward-substituted to xarray[schur,n] will be neglected */ PetscInt i,n,m=0; for (n=0;nnrhs;n++) { for (i=0;ischur_size;i++) { xarray[mat_mkl_pardiso->schur_idxs[i]+m] = 0.; } m += mat_mkl_pardiso->n; } } /* expansion phase */ mat_mkl_pardiso->iparm[6-1] = 1; mat_mkl_pardiso->phase = JOB_SOLVE_BACKWARD_SUBSTITUTION; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, mat_mkl_pardiso->perm, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, (void*)xarray, (void*)mat_mkl_pardiso->schur_work, /* according to the specs, the solution vector is always used */ &mat_mkl_pardiso->err); if (o_schur_work) { /* restore original schur_work (minimal size) */ PetscCall(PetscFree(mat_mkl_pardiso->schur_work)); mat_mkl_pardiso->schur_work = o_schur_work; } PetscCheck(mat_mkl_pardiso->err >= 0,PETSC_COMM_SELF,PETSC_ERR_LIB,"Error reported by MKL_PARDISO: err=%d. Please check manual",mat_mkl_pardiso->err); mat_mkl_pardiso->iparm[6-1] = 0; } PetscCall(MatDenseRestoreArrayWrite(X,&xarray)); } mat_mkl_pardiso->CleanUp = PETSC_TRUE; PetscFunctionReturn(0); } PetscErrorCode MatFactorNumeric_MKL_PARDISO(Mat F,Mat A,const MatFactorInfo *info) { Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)(F)->data; PetscFunctionBegin; mat_mkl_pardiso->matstruc = SAME_NONZERO_PATTERN; PetscCall((*mat_mkl_pardiso->Convert)(A,mat_mkl_pardiso->needsym,MAT_REUSE_MATRIX,&mat_mkl_pardiso->freeaij,&mat_mkl_pardiso->nz,&mat_mkl_pardiso->ia,&mat_mkl_pardiso->ja,(PetscScalar**)&mat_mkl_pardiso->a)); mat_mkl_pardiso->phase = JOB_NUMERICAL_FACTORIZATION; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, mat_mkl_pardiso->perm, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, NULL, (void*)mat_mkl_pardiso->schur, &mat_mkl_pardiso->err); PetscCheck(mat_mkl_pardiso->err >= 0,PETSC_COMM_SELF,PETSC_ERR_LIB,"Error reported by MKL_PARDISO: err=%d. Please check manual",mat_mkl_pardiso->err); /* report flops */ if (mat_mkl_pardiso->iparm[18] > 0) { PetscCall(PetscLogFlops(PetscPowRealInt(10.,6)*mat_mkl_pardiso->iparm[18])); } if (F->schur) { /* schur output from pardiso is in row major format */ #if defined(PETSC_HAVE_CUDA) F->schur->offloadmask = PETSC_OFFLOAD_CPU; #endif PetscCall(MatFactorRestoreSchurComplement(F,NULL,MAT_FACTOR_SCHUR_UNFACTORED)); PetscCall(MatTranspose(F->schur,MAT_INPLACE_MATRIX,&F->schur)); } mat_mkl_pardiso->matstruc = SAME_NONZERO_PATTERN; mat_mkl_pardiso->CleanUp = PETSC_TRUE; PetscFunctionReturn(0); } PetscErrorCode MatSetFromOptions_MKL_PARDISO(Mat F, Mat A) { Mat_MKL_PARDISO *mat_mkl_pardiso = (Mat_MKL_PARDISO*)F->data; PetscInt icntl,bs,threads=1; PetscBool flg; PetscFunctionBegin; PetscOptionsBegin(PetscObjectComm((PetscObject)F),((PetscObject)F)->prefix,"MKL_PARDISO Options","Mat"); PetscCall(PetscOptionsInt("-mat_mkl_pardiso_65","Suggested number of threads to use within PARDISO","None",threads,&threads,&flg)); if (flg) PetscSetMKL_PARDISOThreads((int)threads); PetscCall(PetscOptionsInt("-mat_mkl_pardiso_66","Maximum number of factors with identical sparsity structure that must be kept in memory at the same time","None",mat_mkl_pardiso->maxfct,&icntl,&flg)); if (flg) mat_mkl_pardiso->maxfct = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_67","Indicates the actual matrix for the solution phase","None",mat_mkl_pardiso->mnum,&icntl,&flg)); if (flg) mat_mkl_pardiso->mnum = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_68","Message level information","None",mat_mkl_pardiso->msglvl,&icntl,&flg)); if (flg) mat_mkl_pardiso->msglvl = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_69","Defines the matrix type","None",mat_mkl_pardiso->mtype,&icntl,&flg)); if (flg) { void *pt[IPARM_SIZE]; mat_mkl_pardiso->mtype = icntl; icntl = mat_mkl_pardiso->iparm[34]; bs = mat_mkl_pardiso->iparm[36]; MKL_PARDISO_INIT(pt, &mat_mkl_pardiso->mtype, mat_mkl_pardiso->iparm); #if defined(PETSC_USE_REAL_SINGLE) mat_mkl_pardiso->iparm[27] = 1; #else mat_mkl_pardiso->iparm[27] = 0; #endif mat_mkl_pardiso->iparm[34] = icntl; mat_mkl_pardiso->iparm[36] = bs; } PetscCall(PetscOptionsInt("-mat_mkl_pardiso_1","Use default values (if 0)","None",mat_mkl_pardiso->iparm[0],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[0] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_2","Fill-in reducing ordering for the input matrix","None",mat_mkl_pardiso->iparm[1],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[1] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_4","Preconditioned CGS/CG","None",mat_mkl_pardiso->iparm[3],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[3] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_5","User permutation","None",mat_mkl_pardiso->iparm[4],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[4] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_6","Write solution on x","None",mat_mkl_pardiso->iparm[5],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[5] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_8","Iterative refinement step","None",mat_mkl_pardiso->iparm[7],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[7] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_10","Pivoting perturbation","None",mat_mkl_pardiso->iparm[9],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[9] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_11","Scaling vectors","None",mat_mkl_pardiso->iparm[10],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[10] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_12","Solve with transposed or conjugate transposed matrix A","None",mat_mkl_pardiso->iparm[11],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[11] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_13","Improved accuracy using (non-) symmetric weighted matching","None",mat_mkl_pardiso->iparm[12],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[12] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_18","Numbers of non-zero elements","None",mat_mkl_pardiso->iparm[17],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[17] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_19","Report number of floating point operations (0 to disable)","None",mat_mkl_pardiso->iparm[18],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[18] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_21","Pivoting for symmetric indefinite matrices","None",mat_mkl_pardiso->iparm[20],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[20] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_24","Parallel factorization control","None",mat_mkl_pardiso->iparm[23],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[23] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_25","Parallel forward/backward solve control","None",mat_mkl_pardiso->iparm[24],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[24] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_27","Matrix checker","None",mat_mkl_pardiso->iparm[26],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[26] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_31","Partial solve and computing selected components of the solution vectors","None",mat_mkl_pardiso->iparm[30],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[30] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_34","Optimal number of threads for conditional numerical reproducibility (CNR) mode","None",mat_mkl_pardiso->iparm[33],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[33] = icntl; PetscCall(PetscOptionsInt("-mat_mkl_pardiso_60","Intel MKL_PARDISO mode","None",mat_mkl_pardiso->iparm[59],&icntl,&flg)); if (flg) mat_mkl_pardiso->iparm[59] = icntl; PetscOptionsEnd(); PetscFunctionReturn(0); } PetscErrorCode MatFactorMKL_PARDISOInitialize_Private(Mat A, MatFactorType ftype, Mat_MKL_PARDISO *mat_mkl_pardiso) { PetscInt i,bs; PetscBool match; PetscFunctionBegin; for (i=0; iiparm[i] = 0; for (i=0; ipt[i] = 0; #if defined(PETSC_USE_REAL_SINGLE) mat_mkl_pardiso->iparm[27] = 1; #else mat_mkl_pardiso->iparm[27] = 0; #endif /* Default options for both sym and unsym */ mat_mkl_pardiso->iparm[ 0] = 1; /* Solver default parameters overriden with provided by iparm */ mat_mkl_pardiso->iparm[ 1] = 2; /* Metis reordering */ mat_mkl_pardiso->iparm[ 5] = 0; /* Write solution into x */ mat_mkl_pardiso->iparm[ 7] = 0; /* Max number of iterative refinement steps */ mat_mkl_pardiso->iparm[17] = -1; /* Output: Number of nonzeros in the factor LU */ mat_mkl_pardiso->iparm[18] = -1; /* Output: Mflops for LU factorization */ #if 0 mat_mkl_pardiso->iparm[23] = 1; /* Parallel factorization control*/ #endif PetscCall(PetscObjectTypeCompareAny((PetscObject)A,&match,MATSEQBAIJ,MATSEQSBAIJ,"")); PetscCall(MatGetBlockSize(A,&bs)); if (!match || bs == 1) { mat_mkl_pardiso->iparm[34] = 1; /* Cluster Sparse Solver use C-style indexing for ia and ja arrays */ mat_mkl_pardiso->n = A->rmap->N; } else { mat_mkl_pardiso->iparm[34] = 0; /* Cluster Sparse Solver use Fortran-style indexing for ia and ja arrays */ mat_mkl_pardiso->iparm[36] = bs; mat_mkl_pardiso->n = A->rmap->N/bs; } mat_mkl_pardiso->iparm[39] = 0; /* Input: matrix/rhs/solution stored on rank-0 */ mat_mkl_pardiso->CleanUp = PETSC_FALSE; mat_mkl_pardiso->maxfct = 1; /* Maximum number of numerical factorizations. */ mat_mkl_pardiso->mnum = 1; /* Which factorization to use. */ mat_mkl_pardiso->msglvl = 0; /* 0: do not print 1: Print statistical information in file */ mat_mkl_pardiso->phase = -1; mat_mkl_pardiso->err = 0; mat_mkl_pardiso->nrhs = 1; mat_mkl_pardiso->err = 0; mat_mkl_pardiso->phase = -1; if (ftype == MAT_FACTOR_LU) { mat_mkl_pardiso->iparm[ 9] = 13; /* Perturb the pivot elements with 1E-13 */ mat_mkl_pardiso->iparm[10] = 1; /* Use nonsymmetric permutation and scaling MPS */ mat_mkl_pardiso->iparm[12] = 1; /* Switch on Maximum Weighted Matching algorithm (default for non-symmetric) */ } else { mat_mkl_pardiso->iparm[ 9] = 8; /* Perturb the pivot elements with 1E-8 */ mat_mkl_pardiso->iparm[10] = 0; /* Use nonsymmetric permutation and scaling MPS */ mat_mkl_pardiso->iparm[12] = 1; /* Switch on Maximum Weighted Matching algorithm (default for non-symmetric) */ #if defined(PETSC_USE_DEBUG) mat_mkl_pardiso->iparm[26] = 1; /* Matrix checker */ #endif } PetscCall(PetscCalloc1(A->rmap->N*sizeof(INT_TYPE), &mat_mkl_pardiso->perm)); mat_mkl_pardiso->schur_size = 0; PetscFunctionReturn(0); } PetscErrorCode MatFactorSymbolic_AIJMKL_PARDISO_Private(Mat F,Mat A,const MatFactorInfo *info) { Mat_MKL_PARDISO *mat_mkl_pardiso = (Mat_MKL_PARDISO*)F->data; PetscFunctionBegin; mat_mkl_pardiso->matstruc = DIFFERENT_NONZERO_PATTERN; PetscCall(MatSetFromOptions_MKL_PARDISO(F,A)); /* throw away any previously computed structure */ if (mat_mkl_pardiso->freeaij) { PetscCall(PetscFree2(mat_mkl_pardiso->ia,mat_mkl_pardiso->ja)); if (mat_mkl_pardiso->iparm[34] == 1) { PetscCall(PetscFree(mat_mkl_pardiso->a)); } } PetscCall((*mat_mkl_pardiso->Convert)(A,mat_mkl_pardiso->needsym,MAT_INITIAL_MATRIX,&mat_mkl_pardiso->freeaij,&mat_mkl_pardiso->nz,&mat_mkl_pardiso->ia,&mat_mkl_pardiso->ja,(PetscScalar**)&mat_mkl_pardiso->a)); if (mat_mkl_pardiso->iparm[34] == 1) mat_mkl_pardiso->n = A->rmap->N; else mat_mkl_pardiso->n = A->rmap->N/A->rmap->bs; mat_mkl_pardiso->phase = JOB_ANALYSIS; /* reset flops counting if requested */ if (mat_mkl_pardiso->iparm[18]) mat_mkl_pardiso->iparm[18] = -1; MKL_PARDISO (mat_mkl_pardiso->pt, &mat_mkl_pardiso->maxfct, &mat_mkl_pardiso->mnum, &mat_mkl_pardiso->mtype, &mat_mkl_pardiso->phase, &mat_mkl_pardiso->n, mat_mkl_pardiso->a, mat_mkl_pardiso->ia, mat_mkl_pardiso->ja, mat_mkl_pardiso->perm, &mat_mkl_pardiso->nrhs, mat_mkl_pardiso->iparm, &mat_mkl_pardiso->msglvl, NULL, NULL, &mat_mkl_pardiso->err); PetscCheck(mat_mkl_pardiso->err >= 0,PETSC_COMM_SELF,PETSC_ERR_LIB,"Error reported by MKL_PARDISO: err=%d. Please check manual",mat_mkl_pardiso->err); mat_mkl_pardiso->CleanUp = PETSC_TRUE; if (F->factortype == MAT_FACTOR_LU) F->ops->lufactornumeric = MatFactorNumeric_MKL_PARDISO; else F->ops->choleskyfactornumeric = MatFactorNumeric_MKL_PARDISO; F->ops->solve = MatSolve_MKL_PARDISO; F->ops->solvetranspose = MatSolveTranspose_MKL_PARDISO; F->ops->matsolve = MatMatSolve_MKL_PARDISO; PetscFunctionReturn(0); } PetscErrorCode MatLUFactorSymbolic_AIJMKL_PARDISO(Mat F,Mat A,IS r,IS c,const MatFactorInfo *info) { PetscFunctionBegin; PetscCall(MatFactorSymbolic_AIJMKL_PARDISO_Private(F, A, info)); PetscFunctionReturn(0); } #if !defined(PETSC_USE_COMPLEX) PetscErrorCode MatGetInertia_MKL_PARDISO(Mat F,PetscInt *nneg,PetscInt *nzero,PetscInt *npos) { Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)F->data; PetscFunctionBegin; if (nneg) *nneg = mat_mkl_pardiso->iparm[22]; if (npos) *npos = mat_mkl_pardiso->iparm[21]; if (nzero) *nzero = F->rmap->N - (mat_mkl_pardiso->iparm[22] + mat_mkl_pardiso->iparm[21]); PetscFunctionReturn(0); } #endif PetscErrorCode MatCholeskyFactorSymbolic_AIJMKL_PARDISO(Mat F,Mat A,IS r,const MatFactorInfo *info) { PetscFunctionBegin; PetscCall(MatFactorSymbolic_AIJMKL_PARDISO_Private(F, A, info)); #if defined(PETSC_USE_COMPLEX) F->ops->getinertia = NULL; #else F->ops->getinertia = MatGetInertia_MKL_PARDISO; #endif PetscFunctionReturn(0); } PetscErrorCode MatView_MKL_PARDISO(Mat A, PetscViewer viewer) { PetscBool iascii; PetscViewerFormat format; Mat_MKL_PARDISO *mat_mkl_pardiso=(Mat_MKL_PARDISO*)A->data; PetscInt i; PetscFunctionBegin; if (A->ops->solve != MatSolve_MKL_PARDISO) PetscFunctionReturn(0); PetscCall(PetscObjectTypeCompare((PetscObject)viewer,PETSCVIEWERASCII,&iascii)); if (iascii) { PetscCall(PetscViewerGetFormat(viewer,&format)); if (format == PETSC_VIEWER_ASCII_INFO) { PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO run parameters:\n")); PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO phase: %d \n",mat_mkl_pardiso->phase)); for (i=1; i<=64; i++) { PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO iparm[%d]: %d \n",i, mat_mkl_pardiso->iparm[i - 1])); } PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO maxfct: %d \n", mat_mkl_pardiso->maxfct)); PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO mnum: %d \n", mat_mkl_pardiso->mnum)); PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO mtype: %d \n", mat_mkl_pardiso->mtype)); PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO n: %d \n", mat_mkl_pardiso->n)); PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO nrhs: %d \n", mat_mkl_pardiso->nrhs)); PetscCall(PetscViewerASCIIPrintf(viewer,"MKL_PARDISO msglvl: %d \n", mat_mkl_pardiso->msglvl)); } } PetscFunctionReturn(0); } PetscErrorCode MatGetInfo_MKL_PARDISO(Mat A, MatInfoType flag, MatInfo *info) { Mat_MKL_PARDISO *mat_mkl_pardiso = (Mat_MKL_PARDISO*)A->data; PetscFunctionBegin; info->block_size = 1.0; info->nz_used = mat_mkl_pardiso->iparm[17]; info->nz_allocated = mat_mkl_pardiso->iparm[17]; info->nz_unneeded = 0.0; info->assemblies = 0.0; info->mallocs = 0.0; info->memory = 0.0; info->fill_ratio_given = 0; info->fill_ratio_needed = 0; info->factor_mallocs = 0; PetscFunctionReturn(0); } PetscErrorCode MatMkl_PardisoSetCntl_MKL_PARDISO(Mat F,PetscInt icntl,PetscInt ival) { PetscInt backup,bs; Mat_MKL_PARDISO *mat_mkl_pardiso = (Mat_MKL_PARDISO*)F->data; PetscFunctionBegin; if (icntl <= 64) { mat_mkl_pardiso->iparm[icntl - 1] = ival; } else { if (icntl == 65) PetscSetMKL_PARDISOThreads(ival); else if (icntl == 66) mat_mkl_pardiso->maxfct = ival; else if (icntl == 67) mat_mkl_pardiso->mnum = ival; else if (icntl == 68) mat_mkl_pardiso->msglvl = ival; else if (icntl == 69) { void *pt[IPARM_SIZE]; backup = mat_mkl_pardiso->iparm[34]; bs = mat_mkl_pardiso->iparm[36]; mat_mkl_pardiso->mtype = ival; MKL_PARDISO_INIT(pt, &mat_mkl_pardiso->mtype, mat_mkl_pardiso->iparm); #if defined(PETSC_USE_REAL_SINGLE) mat_mkl_pardiso->iparm[27] = 1; #else mat_mkl_pardiso->iparm[27] = 0; #endif mat_mkl_pardiso->iparm[34] = backup; mat_mkl_pardiso->iparm[36] = bs; } else if (icntl==70) mat_mkl_pardiso->solve_interior = (PetscBool)!!ival; } PetscFunctionReturn(0); } /*@ MatMkl_PardisoSetCntl - Set Mkl_Pardiso parameters Logically Collective on Mat Input Parameters: + F - the factored matrix obtained by calling MatGetFactor() . icntl - index of Mkl_Pardiso parameter - ival - value of Mkl_Pardiso parameter Options Database: . -mat_mkl_pardiso_ - change the option numbered icntl to the value ival Level: beginner References: . * - Mkl_Pardiso Users' Guide .seealso: `MatGetFactor()` @*/ PetscErrorCode MatMkl_PardisoSetCntl(Mat F,PetscInt icntl,PetscInt ival) { PetscFunctionBegin; PetscTryMethod(F,"MatMkl_PardisoSetCntl_C",(Mat,PetscInt,PetscInt),(F,icntl,ival)); PetscFunctionReturn(0); } /*MC MATSOLVERMKL_PARDISO - A matrix type providing direct solvers (LU) for sequential matrices via the external package MKL_PARDISO. Works with MATSEQAIJ matrices Use -pc_type lu -pc_factor_mat_solver_type mkl_pardiso to use this direct solver Options Database Keys: + -mat_mkl_pardiso_65 - Suggested number of threads to use within MKL_PARDISO . -mat_mkl_pardiso_66 - Maximum number of factors with identical sparsity structure that must be kept in memory at the same time . -mat_mkl_pardiso_67 - Indicates the actual matrix for the solution phase . -mat_mkl_pardiso_68 - Message level information, use 1 to get detailed information on the solver options . -mat_mkl_pardiso_69 - Defines the matrix type. IMPORTANT: When you set this flag, iparm parameters are going to be set to the default ones for the matrix type . -mat_mkl_pardiso_1 - Use default values . -mat_mkl_pardiso_2 - Fill-in reducing ordering for the input matrix . -mat_mkl_pardiso_4 - Preconditioned CGS/CG . -mat_mkl_pardiso_5 - User permutation . -mat_mkl_pardiso_6 - Write solution on x . -mat_mkl_pardiso_8 - Iterative refinement step . -mat_mkl_pardiso_10 - Pivoting perturbation . -mat_mkl_pardiso_11 - Scaling vectors . -mat_mkl_pardiso_12 - Solve with transposed or conjugate transposed matrix A . -mat_mkl_pardiso_13 - Improved accuracy using (non-) symmetric weighted matching . -mat_mkl_pardiso_18 - Numbers of non-zero elements . -mat_mkl_pardiso_19 - Report number of floating point operations . -mat_mkl_pardiso_21 - Pivoting for symmetric indefinite matrices . -mat_mkl_pardiso_24 - Parallel factorization control . -mat_mkl_pardiso_25 - Parallel forward/backward solve control . -mat_mkl_pardiso_27 - Matrix checker . -mat_mkl_pardiso_31 - Partial solve and computing selected components of the solution vectors . -mat_mkl_pardiso_34 - Optimal number of threads for conditional numerical reproducibility (CNR) mode - -mat_mkl_pardiso_60 - Intel MKL_PARDISO mode Level: beginner Notes: Use -mat_mkl_pardiso_68 1 to display the number of threads the solver is using. MKL does not provide a way to directly access this information. For more information on the options check the MKL_Pardiso manual .seealso: `PCFactorSetMatSolverType()`, `MatSolverType` M*/ static PetscErrorCode MatFactorGetSolverType_mkl_pardiso(Mat A, MatSolverType *type) { PetscFunctionBegin; *type = MATSOLVERMKL_PARDISO; PetscFunctionReturn(0); } PETSC_EXTERN PetscErrorCode MatGetFactor_aij_mkl_pardiso(Mat A,MatFactorType ftype,Mat *F) { Mat B; Mat_MKL_PARDISO *mat_mkl_pardiso; PetscBool isSeqAIJ,isSeqBAIJ,isSeqSBAIJ; PetscFunctionBegin; PetscCall(PetscObjectBaseTypeCompare((PetscObject)A,MATSEQAIJ,&isSeqAIJ)); PetscCall(PetscObjectTypeCompare((PetscObject)A,MATSEQBAIJ,&isSeqBAIJ)); PetscCall(PetscObjectTypeCompare((PetscObject)A,MATSEQSBAIJ,&isSeqSBAIJ)); PetscCall(MatCreate(PetscObjectComm((PetscObject)A),&B)); PetscCall(MatSetSizes(B,A->rmap->n,A->cmap->n,A->rmap->N,A->cmap->N)); PetscCall(PetscStrallocpy("mkl_pardiso",&((PetscObject)B)->type_name)); PetscCall(MatSetUp(B)); PetscCall(PetscNewLog(B,&mat_mkl_pardiso)); B->data = mat_mkl_pardiso; PetscCall(MatFactorMKL_PARDISOInitialize_Private(A, ftype, mat_mkl_pardiso)); if (ftype == MAT_FACTOR_LU) { B->ops->lufactorsymbolic = MatLUFactorSymbolic_AIJMKL_PARDISO; B->factortype = MAT_FACTOR_LU; mat_mkl_pardiso->needsym = PETSC_FALSE; if (isSeqAIJ) mat_mkl_pardiso->Convert = MatMKLPardiso_Convert_seqaij; else if (isSeqBAIJ) mat_mkl_pardiso->Convert = MatMKLPardiso_Convert_seqbaij; else { PetscCheck(!isSeqSBAIJ,PetscObjectComm((PetscObject)A),PETSC_ERR_SUP,"No support for PARDISO LU factor with SEQSBAIJ format! Use MAT_FACTOR_CHOLESKY instead"); SETERRQ(PetscObjectComm((PetscObject)A),PETSC_ERR_SUP,"No support for PARDISO LU with %s format",((PetscObject)A)->type_name); } #if defined(PETSC_USE_COMPLEX) mat_mkl_pardiso->mtype = 13; #else mat_mkl_pardiso->mtype = 11; #endif } else { B->ops->choleskyfactorsymbolic = MatCholeskyFactorSymbolic_AIJMKL_PARDISO; B->factortype = MAT_FACTOR_CHOLESKY; if (isSeqAIJ) mat_mkl_pardiso->Convert = MatMKLPardiso_Convert_seqaij; else if (isSeqBAIJ) mat_mkl_pardiso->Convert = MatMKLPardiso_Convert_seqbaij; else if (isSeqSBAIJ) mat_mkl_pardiso->Convert = MatMKLPardiso_Convert_seqsbaij; else SETERRQ(PetscObjectComm((PetscObject)A),PETSC_ERR_SUP,"No support for PARDISO CHOLESKY with %s format",((PetscObject)A)->type_name); mat_mkl_pardiso->needsym = PETSC_TRUE; #if !defined(PETSC_USE_COMPLEX) if (A->spd == PETSC_BOOL3_TRUE) mat_mkl_pardiso->mtype = 2; else mat_mkl_pardiso->mtype = -2; #else mat_mkl_pardiso->mtype = 6; PetscCheck(A->hermitian != PETSC_BOOL3_TRUE,PetscObjectComm((PetscObject)A),PETSC_ERR_SUP,"No support for PARDISO CHOLESKY with Hermitian matrices! Use MAT_FACTOR_LU instead"); #endif } B->ops->destroy = MatDestroy_MKL_PARDISO; B->ops->view = MatView_MKL_PARDISO; B->ops->getinfo = MatGetInfo_MKL_PARDISO; B->factortype = ftype; B->assembled = PETSC_TRUE; PetscCall(PetscFree(B->solvertype)); PetscCall(PetscStrallocpy(MATSOLVERMKL_PARDISO,&B->solvertype)); PetscCall(PetscObjectComposeFunction((PetscObject)B,"MatFactorGetSolverType_C",MatFactorGetSolverType_mkl_pardiso)); PetscCall(PetscObjectComposeFunction((PetscObject)B,"MatFactorSetSchurIS_C",MatFactorSetSchurIS_MKL_PARDISO)); PetscCall(PetscObjectComposeFunction((PetscObject)B,"MatMkl_PardisoSetCntl_C",MatMkl_PardisoSetCntl_MKL_PARDISO)); *F = B; PetscFunctionReturn(0); } PETSC_EXTERN PetscErrorCode MatSolverTypeRegister_MKL_Pardiso(void) { PetscFunctionBegin; PetscCall(MatSolverTypeRegister(MATSOLVERMKL_PARDISO,MATSEQAIJ,MAT_FACTOR_LU,MatGetFactor_aij_mkl_pardiso)); PetscCall(MatSolverTypeRegister(MATSOLVERMKL_PARDISO,MATSEQAIJ,MAT_FACTOR_CHOLESKY,MatGetFactor_aij_mkl_pardiso)); PetscCall(MatSolverTypeRegister(MATSOLVERMKL_PARDISO,MATSEQBAIJ,MAT_FACTOR_LU,MatGetFactor_aij_mkl_pardiso)); PetscCall(MatSolverTypeRegister(MATSOLVERMKL_PARDISO,MATSEQSBAIJ,MAT_FACTOR_CHOLESKY,MatGetFactor_aij_mkl_pardiso)); PetscFunctionReturn(0); }