#include #include #include #include #include /*I "petscksp.h" I*/ #include "petscsection.h" #include #include "Kokkos_Core.hpp" #include <../src/mat/impls/aij/seq/aij.h> #include <../src/mat/impls/aij/seq/kokkos/aijkok.hpp> #if defined(PETSC_HAVE_CUDA) #include #endif #include #define PCBJKOKKOS_SHARED_LEVEL 0 // 0 is shared, 1 is global #define PCBJKOKKOS_VEC_SIZE 16 #define PCBJKOKKOS_TEAM_SIZE 16 #define PCBJKOKKOS_VERBOSE_LEVEL 2 typedef Kokkos::DefaultExecutionSpace exec_space; using layout = Kokkos::LayoutRight; using IntView = Kokkos::View; using AMatrixValueView = const Kokkos::View; using XYType = const Kokkos::View; typedef enum { BATCH_KSP_BICG_IDX, BATCH_KSP_TFQMR_IDX, BATCH_KSP_GMRES_IDX, NUM_BATCH_TYPES } KSPIndex; typedef struct { Vec vec_diag; PetscInt nBlocks; /* total number of blocks */ PetscInt n; // cache host version of d_bid_eqOffset_k[nBlocks] KSP ksp; // Used just for options. Should have one for each block Kokkos::View *d_bid_eqOffset_k; Kokkos::View *d_idiag_k; Kokkos::View *d_isrow_k; Kokkos::View *d_isicol_k; KSPIndex ksp_type_idx; PetscInt nwork; PetscInt const_block_size; // used to decide to use shared memory for work vectors PetscInt *dm_Nf; // Number of fields in each DM PetscInt num_dms; // diagnostics PetscBool reason; PetscBool monitor; PetscInt batch_target; PetscInt nsolves_team; PetscInt max_nits; // caches IntView *rowOffsets; IntView *colIndices; XYType *batch_b; XYType *batch_x; AMatrixValueView *batch_values; } PC_PCBJKOKKOS; #if defined(PETSC_HAVE_KOKKOS_KERNELS_GMRES) #include #include "Kokkos_Timer.hpp" #include "Kokkos_Random.hpp" #include "Kokkos_UnorderedMap.hpp" #include "Kokkos_Sort.hpp" /// KokkosKernels headers #include "KokkosBatched_Util.hpp" #include "KokkosBatched_Vector.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "KokkosBatched_Spmv.hpp" #include "KokkosBatched_CrsMatrix.hpp" #include "KokkosBatched_Krylov_Handle.hpp" #include "KokkosBatched_GMRES.hpp" #include "KokkosBatched_JacobiPrec.hpp" template struct Functor_TestBatchedTeamVectorGMRES { const ValuesViewType _D; const ValuesViewType _diag; const IntView _r; const IntView _c; const VectorViewType _X; const VectorViewType _B; const int _N_team, _team_size, _vector_length; const int _N_iteration; const double _tol; const int _ortho_strategy; const int _scratch_pad_level; KrylovHandleType _handle; KOKKOS_INLINE_FUNCTION Functor_TestBatchedTeamVectorGMRES(const ValuesViewType &D, const IntView &r, const IntView &c, const VectorViewType &X, const VectorViewType &B, const int N_team, const int team_size, const int vector_length, const int N_iteration, const double tol, const int ortho_strategy, const int scratch_pad_level, KrylovHandleType &handle) : _D(D), _r(r), _c(c), _X(X), _B(B), _N_team(N_team), _team_size(team_size), _vector_length(vector_length), _N_iteration(N_iteration), _tol(tol), _ortho_strategy(ortho_strategy), _scratch_pad_level(scratch_pad_level), _handle(handle) { } KOKKOS_INLINE_FUNCTION Functor_TestBatchedTeamVectorGMRES(const ValuesViewType &D, const ValuesViewType &diag, const IntView &r, const IntView &c, const VectorViewType &X, const VectorViewType &B, const int N_team, const int team_size, const int vector_length, const int N_iteration, const double tol, int ortho_strategy, const int scratch_pad_level, KrylovHandleType &handle) : _D(D), _diag(diag), _r(r), _c(c), _X(X), _B(B), _N_team(N_team), _team_size(team_size), _vector_length(vector_length), _N_iteration(N_iteration), _tol(tol), _ortho_strategy(ortho_strategy), _scratch_pad_level(scratch_pad_level), _handle(handle) { } template KOKKOS_INLINE_FUNCTION void operator()(const MemberType &member) const { const int first_matrix = static_cast(member.league_rank()) * _N_team; const int N = _D.extent(0); const int last_matrix = (static_cast(member.league_rank() + 1) * _N_team < N ? static_cast(member.league_rank() + 1) * _N_team : N); const int graphID = static_cast(member.league_rank()); using TeamVectorCopy1D = KokkosBatched::TeamVectorCopy; auto d = Kokkos::subview(_D, Kokkos::make_pair(first_matrix, last_matrix), Kokkos::ALL); auto x = Kokkos::subview(_X, Kokkos::make_pair(first_matrix, last_matrix), Kokkos::ALL); auto b = Kokkos::subview(_B, Kokkos::make_pair(first_matrix, last_matrix), Kokkos::ALL); using ScratchPadIntViewType = Kokkos::View; using ScratchPadValuesViewType = Kokkos::View; using Operator = KokkosBatched::CrsMatrix; ScratchPadIntViewType r(member.team_scratch(1), _r.extent(1)); ScratchPadIntViewType c(member.team_scratch(1), _c.extent(1)); TeamVectorCopy1D::invoke(member, Kokkos::subview(_r, graphID, Kokkos::ALL), r); TeamVectorCopy1D::invoke(member, Kokkos::subview(_c, graphID, Kokkos::ALL), c); Operator A(d, r, c); ScratchPadValuesViewType diag(member.team_scratch(1), last_matrix - first_matrix, _diag.extent(1)); using PrecOperator = KokkosBatched::JacobiPrec; KokkosBatched::TeamVectorCopy::invoke(member, Kokkos::subview(_diag, Kokkos::make_pair(first_matrix, last_matrix), Kokkos::ALL), diag); PrecOperator P(diag); P.setComputedInverse(); KokkosBatched::TeamVectorGMRES::template invoke(member, A, b, x, P, _handle); } inline double run(PC pc) { typedef typename ValuesViewType::value_type value_type; std::string name("KokkosBatched::Test::TeamVectorGMRES"); Kokkos::Timer timer; Kokkos::Profiling::pushRegion(name.c_str()); Kokkos::TeamPolicy auto_policy(ceil(1. * _D.extent(0) / _N_team), Kokkos::AUTO(), Kokkos::AUTO()); Kokkos::TeamPolicy tuned_policy(ceil(1. * _D.extent(0) / _N_team), _team_size, _vector_length); Kokkos::TeamPolicy policy; if (_team_size < 1) policy = auto_policy; else policy = tuned_policy; _handle.set_max_iteration(_N_iteration); _handle.set_tolerance(_tol); _handle.set_ortho_strategy(_ortho_strategy); _handle.set_scratch_pad_level(_scratch_pad_level); _handle.set_compute_last_residual(true); int maximum_iteration = _handle.get_max_iteration(); using ScalarType = typename ValuesViewType::non_const_value_type; using Layout = typename ValuesViewType::array_layout; using EXSP = typename ValuesViewType::execution_space; using MagnitudeType = typename Kokkos::Details::ArithTraits::mag_type; using ViewType1D = Kokkos::View; using ViewType2D = Kokkos::View; using ViewType3D = Kokkos::View; using IntViewType1D = Kokkos::View; size_t bytes_1D = ViewType2D::shmem_size(_N_team, 1); size_t bytes_row_ptr = IntViewType1D::shmem_size(_r.extent(1)); size_t bytes_col_idc = IntViewType1D::shmem_size(_c.extent(1)); size_t bytes_2D_1 = ViewType2D::shmem_size(_N_team, _X.extent(1)); size_t bytes_2D_2 = ViewType2D::shmem_size(_N_team, maximum_iteration + 1); size_t bytes_diag = bytes_2D_1; size_t bytes_tmp = 2 * bytes_2D_1 + 2 * bytes_1D + bytes_2D_2; policy.set_scratch_size(0, Kokkos::PerTeam(bytes_tmp)); policy.set_scratch_size(1, Kokkos::PerTeam(bytes_col_idc + bytes_row_ptr + bytes_diag)); PetscInfo(pc, "%d scratch memory(0) = %d + %d + %d bytes_diag=%d; %d scratch memory(1); %d maximum_iterations\n", (int)(bytes_tmp), 2 * (int)bytes_2D_1, 2 * (int)bytes_1D, (int)bytes_2D_2, (int)bytes_diag, (int)(bytes_row_ptr + bytes_col_idc + bytes_diag), (int)maximum_iteration); exec_space().fence(); timer.reset(); Kokkos::parallel_for(name.c_str(), policy, *this); exec_space().fence(); double sec = timer.seconds(); return sec; } }; #endif // KK GMRES typedef Kokkos::TeamPolicy<>::member_type team_member; static PetscErrorCode PCBJKOKKOSCreateKSP_BJKOKKOS(PC pc) { const char *prefix; PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; DM dm; PetscFunctionBegin; PetscCall(KSPCreate(PetscObjectComm((PetscObject)pc), &jac->ksp)); PetscCall(KSPSetErrorIfNotConverged(jac->ksp, pc->erroriffailure)); PetscCall(PetscObjectIncrementTabLevel((PetscObject)jac->ksp, (PetscObject)pc, 1)); PetscCall(PCGetOptionsPrefix(pc, &prefix)); PetscCall(KSPSetOptionsPrefix(jac->ksp, prefix)); PetscCall(KSPAppendOptionsPrefix(jac->ksp, "pc_bjkokkos_")); PetscCall(PCGetDM(pc, &dm)); if (dm) { PetscCall(KSPSetDM(jac->ksp, dm)); PetscCall(KSPSetDMActive(jac->ksp, PETSC_FALSE)); } jac->reason = PETSC_FALSE; jac->monitor = PETSC_FALSE; jac->batch_target = -1; jac->nsolves_team = 1; jac->ksp->max_it = 50; // this is realy for GMRES w/o restarts PetscFunctionReturn(0); } // y <-- Ax KOKKOS_INLINE_FUNCTION PetscErrorCode MatMult(const team_member team, const PetscInt *glb_Aai, const PetscInt *glb_Aaj, const PetscScalar *glb_Aaa, const PetscInt *r, const PetscInt *ic, const PetscInt start, const PetscInt end, const PetscScalar *x_loc, PetscScalar *y_loc) { Kokkos::parallel_for(Kokkos::TeamThreadRange(team, start, end), [=](const int rowb) { int rowa = ic[rowb]; int n = glb_Aai[rowa + 1] - glb_Aai[rowa]; const PetscInt *aj = glb_Aaj + glb_Aai[rowa]; const PetscScalar *aa = glb_Aaa + glb_Aai[rowa]; PetscScalar sum; Kokkos::parallel_reduce( Kokkos::ThreadVectorRange(team, n), [=](const int i, PetscScalar &lsum) { lsum += aa[i] * x_loc[r[aj[i]] - start]; }, sum); Kokkos::single(Kokkos::PerThread(team), [=]() { y_loc[rowb - start] = sum; }); }); team.team_barrier(); return 0; } // temp buffer per thread with reduction at end? KOKKOS_INLINE_FUNCTION PetscErrorCode MatMultTranspose(const team_member team, const PetscInt *glb_Aai, const PetscInt *glb_Aaj, const PetscScalar *glb_Aaa, const PetscInt *r, const PetscInt *ic, const PetscInt start, const PetscInt end, const PetscScalar *x_loc, PetscScalar *y_loc) { Kokkos::parallel_for(Kokkos::TeamVectorRange(team, end - start), [=](int i) { y_loc[i] = 0; }); team.team_barrier(); Kokkos::parallel_for(Kokkos::TeamThreadRange(team, start, end), [=](const int rowb) { int rowa = ic[rowb]; int n = glb_Aai[rowa + 1] - glb_Aai[rowa]; const PetscInt *aj = glb_Aaj + glb_Aai[rowa]; const PetscScalar *aa = glb_Aaa + glb_Aai[rowa]; const PetscScalar xx = x_loc[rowb - start]; // rowb = ic[rowa] = ic[r[rowb]] Kokkos::parallel_for(Kokkos::ThreadVectorRange(team, n), [=](const int &i) { PetscScalar val = aa[i] * xx; Kokkos::atomic_fetch_add(&y_loc[r[aj[i]] - start], val); }); }); team.team_barrier(); return 0; } typedef struct Batch_MetaData_TAG { PetscInt flops; PetscInt its; KSPConvergedReason reason; } Batch_MetaData; // Solve A(BB^-1)x = y with TFQMR. Right preconditioned to get un-preconditioned residual KOKKOS_INLINE_FUNCTION PetscErrorCode BJSolve_TFQMR(const team_member team, const PetscInt *glb_Aai, const PetscInt *glb_Aaj, const PetscScalar *glb_Aaa, const PetscInt *r, const PetscInt *ic, PetscScalar *work_space_global, const int stride_global, const int nShareVec, PetscScalar *work_space_shared, const int stride_shared, PetscReal rtol, PetscReal atol, PetscReal dtol, PetscInt maxit, Batch_MetaData *metad, const PetscInt start, const PetscInt end, const PetscScalar glb_idiag[], const PetscScalar *glb_b, PetscScalar *glb_x, bool monitor) { using Kokkos::parallel_for; using Kokkos::parallel_reduce; int Nblk = end - start, i, m, stride = stride_shared, idx = 0; PetscReal dp, dpold, w, dpest, tau, psi, cm, r0; const PetscScalar *Diag = &glb_idiag[start]; PetscScalar *ptr = work_space_shared, rho, rhoold, a, s, b, eta, etaold, psiold, cf, dpi; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *XX = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *R = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *RP = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *V = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *T = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Q = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *P = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *U = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *D = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *AUQ = V; // init: get b, zero x parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](int rowb) { int rowa = ic[rowb]; R[rowb - start] = glb_b[rowa]; XX[rowb - start] = 0; }); team.team_barrier(); parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &lsum) { lsum += R[idx] * PetscConj(R[idx]); }, dpi); team.team_barrier(); r0 = dp = PetscSqrtReal(PetscRealPart(dpi)); // diagnostics #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (monitor) Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("%3d KSP Residual norm %14.12e \n", 0, (double)dp); }); #endif if (dp < atol) { metad->reason = KSP_CONVERGED_ATOL_NORMAL; return 0; } if (0 == maxit) { metad->reason = KSP_DIVERGED_ITS; return 0; } /* Make the initial Rp = R */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { RP[idx] = R[idx]; }); team.team_barrier(); /* Set the initial conditions */ etaold = 0.0; psiold = 0.0; tau = dp; dpold = dp; /* rhoold = (r,rp) */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &dot) { dot += R[idx] * PetscConj(RP[idx]); }, rhoold); team.team_barrier(); parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { U[idx] = R[idx]; P[idx] = R[idx]; T[idx] = Diag[idx] * P[idx]; D[idx] = 0; }); team.team_barrier(); MatMult(team, glb_Aai, glb_Aaj, glb_Aaa, r, ic, start, end, T, V); i = 0; do { /* s <- (v,rp) */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &dot) { dot += V[idx] * PetscConj(RP[idx]); }, s); team.team_barrier(); a = rhoold / s; /* a <- rho / s */ /* q <- u - a v VecWAXPY(w,alpha,x,y): w = alpha x + y. */ /* t <- u + q */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { Q[idx] = U[idx] - a * V[idx]; T[idx] = U[idx] + Q[idx]; }); team.team_barrier(); // KSP_PCApplyBAorAB parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { T[idx] = Diag[idx] * T[idx]; }); team.team_barrier(); MatMult(team, glb_Aai, glb_Aaj, glb_Aaa, r, ic, start, end, T, AUQ); /* r <- r - a K (u + q) */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { R[idx] = R[idx] - a * AUQ[idx]; }); team.team_barrier(); parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &lsum) { lsum += R[idx] * PetscConj(R[idx]); }, dpi); team.team_barrier(); dp = PetscSqrtReal(PetscRealPart(dpi)); for (m = 0; m < 2; m++) { if (!m) w = PetscSqrtReal(dp * dpold); else w = dp; psi = w / tau; cm = 1.0 / PetscSqrtReal(1.0 + psi * psi); tau = tau * psi * cm; eta = cm * cm * a; cf = psiold * psiold * etaold / a; if (!m) { /* D = U + cf D */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { D[idx] = U[idx] + cf * D[idx]; }); } else { /* D = Q + cf D */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { D[idx] = Q[idx] + cf * D[idx]; }); } team.team_barrier(); parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { XX[idx] = XX[idx] + eta * D[idx]; }); team.team_barrier(); dpest = PetscSqrtReal(2 * i + m + 2.0) * tau; #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (monitor && m == 1) Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("%3d KSP Residual norm %14.12e \n", i + 1, (double)dpest); }); #endif if (dpest < atol) { metad->reason = KSP_CONVERGED_ATOL_NORMAL; goto done; } if (dpest / r0 < rtol) { metad->reason = KSP_CONVERGED_RTOL_NORMAL; goto done; } #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (dpest / r0 > dtol) { metad->reason = KSP_DIVERGED_DTOL; Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("ERROR block %d diverged: %d it, res=%e, r_0=%e\n", team.league_rank(), i, dpest, r0); }); goto done; } #else if (dpest / r0 > dtol) { metad->reason = KSP_DIVERGED_DTOL; goto done; } #endif if (i + 1 == maxit) { metad->reason = KSP_DIVERGED_ITS; goto done; } etaold = eta; psiold = psi; } /* rho <- (r,rp) */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &dot) { dot += R[idx] * PetscConj(RP[idx]); }, rho); team.team_barrier(); b = rho / rhoold; /* b <- rho / rhoold */ /* u <- r + b q */ /* p <- u + b(q + b p) */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { U[idx] = R[idx] + b * Q[idx]; Q[idx] = Q[idx] + b * P[idx]; P[idx] = U[idx] + b * Q[idx]; }); /* v <- K p */ team.team_barrier(); parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { T[idx] = Diag[idx] * P[idx]; }); team.team_barrier(); MatMult(team, glb_Aai, glb_Aaj, glb_Aaa, r, ic, start, end, T, V); rhoold = rho; dpold = dp; i++; } while (i < maxit); done: // KSPUnwindPreconditioner parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { XX[idx] = Diag[idx] * XX[idx]; }); team.team_barrier(); // put x into Plex order parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](int rowb) { int rowa = ic[rowb]; glb_x[rowa] = XX[rowb - start]; }); metad->its = i + 1; if (1) { int nnz; parallel_reduce( Kokkos::TeamVectorRange(team, start, end), [=](const int idx, int &lsum) { lsum += (glb_Aai[idx + 1] - glb_Aai[idx]); }, nnz); metad->flops = 2 * (metad->its * (10 * Nblk + 2 * nnz) + 5 * Nblk); } else { metad->flops = 2 * (metad->its * (10 * Nblk + 2 * 50 * Nblk) + 5 * Nblk); // guess } return 0; } // Solve Ax = y with biCG KOKKOS_INLINE_FUNCTION PetscErrorCode BJSolve_BICG(const team_member team, const PetscInt *glb_Aai, const PetscInt *glb_Aaj, const PetscScalar *glb_Aaa, const PetscInt *r, const PetscInt *ic, PetscScalar *work_space_global, const int stride_global, const int nShareVec, PetscScalar *work_space_shared, const int stride_shared, PetscReal rtol, PetscReal atol, PetscReal dtol, PetscInt maxit, Batch_MetaData *metad, const PetscInt start, const PetscInt end, const PetscScalar glb_idiag[], const PetscScalar *glb_b, PetscScalar *glb_x, bool monitor) { using Kokkos::parallel_for; using Kokkos::parallel_reduce; int Nblk = end - start, i, stride = stride_shared, idx = 0; // start in shared mem PetscReal dp, r0; const PetscScalar *Di = &glb_idiag[start]; PetscScalar *ptr = work_space_shared, dpi, a = 1.0, beta, betaold = 1.0, b, b2, ma, mac; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *XX = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Rl = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Zl = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Pl = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Rr = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Zr = ptr; ptr += stride; if (idx++ == nShareVec) { ptr = work_space_global; stride = stride_global; } PetscScalar *Pr = ptr; ptr += stride; /* r <- b (x is 0) */ parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](int rowb) { int rowa = ic[rowb]; //PetscCall(VecCopy(Rr,Rl)); Rl[rowb - start] = Rr[rowb - start] = glb_b[rowa]; XX[rowb - start] = 0; }); team.team_barrier(); /* z <- Br */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { Zr[idx] = Di[idx] * Rr[idx]; Zl[idx] = Di[idx] * Rl[idx]; }); team.team_barrier(); /* dp <- r'*r */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &lsum) { lsum += Rr[idx] * PetscConj(Rr[idx]); }, dpi); team.team_barrier(); r0 = dp = PetscSqrtReal(PetscRealPart(dpi)); #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (monitor) Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("%3d KSP Residual norm %14.12e \n", 0, (double)dp); }); #endif if (dp < atol) { metad->reason = KSP_CONVERGED_ATOL_NORMAL; return 0; } if (0 == maxit) { metad->reason = KSP_DIVERGED_ITS; return 0; } i = 0; do { /* beta <- r'z */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &dot) { dot += Zr[idx] * PetscConj(Rl[idx]); }, beta); team.team_barrier(); #if PCBJKOKKOS_VERBOSE_LEVEL >= 6 #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("%7d beta = Z.R = %22.14e \n", i, (double)beta); }); #endif #endif if (!i) { if (beta == 0.0) { metad->reason = KSP_DIVERGED_BREAKDOWN_BICG; goto done; } /* p <- z */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { Pr[idx] = Zr[idx]; Pl[idx] = Zl[idx]; }); } else { b = beta / betaold; /* p <- z + b* p */ b2 = PetscConj(b); parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { Pr[idx] = b * Pr[idx] + Zr[idx]; Pl[idx] = b2 * Pl[idx] + Zl[idx]; }); } team.team_barrier(); betaold = beta; /* z <- Kp */ MatMult(team, glb_Aai, glb_Aaj, glb_Aaa, r, ic, start, end, Pr, Zr); MatMultTranspose(team, glb_Aai, glb_Aaj, glb_Aaa, r, ic, start, end, Pl, Zl); /* dpi <- z'p */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &lsum) { lsum += Zr[idx] * PetscConj(Pl[idx]); }, dpi); team.team_barrier(); // a = beta / dpi; /* a = beta/p'z */ ma = -a; mac = PetscConj(ma); /* x <- x + ap */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { XX[idx] = XX[idx] + a * Pr[idx]; Rr[idx] = Rr[idx] + ma * Zr[idx]; Rl[idx] = Rl[idx] + mac * Zl[idx]; }); team.team_barrier(); team.team_barrier(); /* dp <- r'*r */ parallel_reduce( Kokkos::TeamVectorRange(team, Nblk), [=](const int idx, PetscScalar &lsum) { lsum += Rr[idx] * PetscConj(Rr[idx]); }, dpi); team.team_barrier(); dp = PetscSqrtReal(PetscRealPart(dpi)); #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (monitor) Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("%3d KSP Residual norm %14.12e \n", i + 1, (double)dp); }); #endif if (dp < atol) { metad->reason = KSP_CONVERGED_ATOL_NORMAL; goto done; } if (dp / r0 < rtol) { metad->reason = KSP_CONVERGED_RTOL_NORMAL; goto done; } #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (dp / r0 > dtol) { metad->reason = KSP_DIVERGED_DTOL; Kokkos::single(Kokkos::PerTeam(team), [=]() { printf("ERROR block %d diverged: %d it, res=%e, r_0=%e\n", team.league_rank(), i, dp, r0); }); goto done; } #else if (dp / r0 > dtol) { metad->reason = KSP_DIVERGED_DTOL; goto done; } #endif if (i + 1 == maxit) { metad->reason = KSP_DIVERGED_ITS; goto done; } /* z <- Br */ parallel_for(Kokkos::TeamVectorRange(team, Nblk), [=](int idx) { Zr[idx] = Di[idx] * Rr[idx]; Zl[idx] = Di[idx] * Rl[idx]; }); i++; team.team_barrier(); } while (i < maxit); done: // put x back into Plex order parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](int rowb) { int rowa = ic[rowb]; glb_x[rowa] = XX[rowb - start]; }); metad->its = i + 1; if (1) { int nnz; parallel_reduce( Kokkos::TeamVectorRange(team, start, end), [=](const int idx, int &lsum) { lsum += (glb_Aai[idx + 1] - glb_Aai[idx]); }, nnz); metad->flops = 2 * (metad->its * (10 * Nblk + 2 * nnz) + 5 * Nblk); } else { metad->flops = 2 * (metad->its * (10 * Nblk + 2 * 50 * Nblk) + 5 * Nblk); // guess } return 0; } // KSP solver solve Ax = b; x is output, bin is input static PetscErrorCode PCApply_BJKOKKOS(PC pc, Vec bin, Vec xout) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; Mat A = pc->pmat; Mat_SeqAIJKokkos *aijkok; PetscFunctionBegin; aijkok = static_cast(A->spptr); PetscCheck(aijkok, PetscObjectComm((PetscObject)pc), PETSC_ERR_USER, "No aijkok"); { PetscInt maxit = jac->ksp->max_it; const PetscInt conc = Kokkos::DefaultExecutionSpace().concurrency(), openmp = !!(conc < 1000), team_size = (openmp == 0 && PCBJKOKKOS_VEC_SIZE != 1) ? PCBJKOKKOS_TEAM_SIZE : 1; const PetscInt nwork = jac->nwork, nBlk = jac->nBlocks; PetscScalar *glb_xdata = NULL; PetscReal rtol = jac->ksp->rtol, atol = jac->ksp->abstol, dtol = jac->ksp->divtol; const PetscScalar *glb_idiag = jac->d_idiag_k->data(), *glb_bdata = NULL; const PetscInt *glb_Aai = aijkok->i_device_data(), *glb_Aaj = aijkok->j_device_data(), *d_bid_eqOffset = jac->d_bid_eqOffset_k->data(); const PetscScalar *glb_Aaa = aijkok->a_device_data(); const PetscInt *d_isicol = jac->d_isicol_k->data(), *d_isrow = jac->d_isrow_k->data(); PCFailedReason pcreason; KSPIndex ksp_type_idx = jac->ksp_type_idx; PetscMemType mtype; PetscContainer container; PetscInt batch_sz; VecScatter plex_batch = NULL; // not used Vec bvec; // a copy of b for scatter (just alias to bin now) PetscBool monitor = jac->monitor; // captured PetscInt view_bid = jac->batch_target; MatInfo info; jac->max_nits = 0; if (view_bid < 0) view_bid = 0; PetscCall(MatGetInfo(A, MAT_LOCAL, &info)); // get field major is to map plex IO to/from block/field major PetscCall(PetscObjectQuery((PetscObject)A, "plex_batch_is", (PetscObject *)&container)); if (container) { PetscCall(VecDuplicate(bin, &bvec)); PetscCall(PetscContainerGetPointer(container, (void **)&plex_batch)); PetscCall(VecScatterBegin(plex_batch, bin, bvec, INSERT_VALUES, SCATTER_FORWARD)); PetscCall(VecScatterEnd(plex_batch, bin, bvec, INSERT_VALUES, SCATTER_FORWARD)); SETERRQ(PetscObjectComm((PetscObject)A), PETSC_ERR_USER, "No plex_batch_is -- require NO field major ordering for now"); } else { bvec = bin; } // get x PetscCall(VecGetArrayAndMemType(xout, &glb_xdata, &mtype)); #if defined(PETSC_HAVE_CUDA) PetscCheck(PetscMemTypeDevice(mtype), PetscObjectComm((PetscObject)pc), PETSC_ERR_ARG_WRONG, "No GPU data for x %" PetscInt_FMT " != %" PetscInt_FMT, mtype, PETSC_MEMTYPE_DEVICE); #endif PetscCall(VecGetArrayReadAndMemType(bvec, &glb_bdata, &mtype)); #if defined(PETSC_HAVE_CUDA) PetscCheck(PetscMemTypeDevice(mtype), PetscObjectComm((PetscObject)pc), PETSC_ERR_ARG_WRONG, "No GPU data for b"); #endif // get batch size PetscCall(PetscObjectQuery((PetscObject)A, "batch size", (PetscObject *)&container)); if (container) { PetscInt *pNf = NULL; PetscCall(PetscContainerGetPointer(container, (void **)&pNf)); batch_sz = *pNf; } else batch_sz = 1; PetscCheck(nBlk % batch_sz == 0, PetscObjectComm((PetscObject)pc), PETSC_ERR_ARG_WRONG, "batch_sz = %" PetscInt_FMT ", nBlk = %" PetscInt_FMT, batch_sz, nBlk); if (ksp_type_idx == BATCH_KSP_GMRES_IDX) { // KK solver - move PETSc data into Kokkos Views, setup solver, solve, move data out of Kokkos, process metadata (convergence tests, etc.) #if defined(PETSC_HAVE_KOKKOS_KERNELS_GMRES) int Nsolves_team = jac->nsolves_team, fill_idx = 0; int Nloc = jac->const_block_size; // same grids const int Nsolves = nBlk; const int nnz = (int)info.nz_used / Nsolves; // fix for variable grid size if (Nsolves_team > batch_sz) Nsolves_team = batch_sz; // silently fix this PetscCheck(jac->const_block_size, PetscObjectComm((PetscObject)pc), PETSC_ERR_ARG_WRONG, "Kokkos (GMRES) solver requires constant block size (but can be made to work with species ordering or N_team==1)"); PetscCheck(Nsolves % Nsolves_team == 0, PetscObjectComm((PetscObject)pc), PETSC_ERR_ARG_WRONG, "Nsolves.mod(Nsolves_team) != 0: Nsolves = %d, Nsolves_team = %d", Nsolves, Nsolves_team); PetscCheck(((int)info.nz_used) % Nsolves == 0, PetscObjectComm((PetscObject)pc), PETSC_ERR_ARG_WRONG, "info.nz_used.mod(Nsolves) != 0: info.nz_used = %g, Nsolves = %d", info.nz_used, Nsolves); #if defined(PETSC_HAVE_CUDA) nvtxRangePushA("gmres-kk"); #endif Kokkos::View> inv_diag((PetscScalar *)glb_idiag, Nsolves, Nloc); // in correct order if (!jac->rowOffsets) { jac->rowOffsets = new IntView("rowOffsets", Nsolves / Nsolves_team, Nloc + 1); // same grids jac->colIndices = new IntView("colIndices", Nsolves / Nsolves_team, nnz); jac->batch_b = new XYType("batch rhs", Nsolves, Nloc); jac->batch_x = new XYType("batch sol", Nsolves, Nloc); jac->batch_values = new AMatrixValueView("batch values", Nsolves, nnz); fill_idx = 1; PetscInfo(pc, "Setup indices Nloc=%d, nnz=%d\n", Nloc, nnz); } IntView &rowOffsets = *jac->rowOffsets; IntView &colIndices = *jac->colIndices; XYType &batch_b = *jac->batch_b; XYType &batch_x = *jac->batch_x; AMatrixValueView &batch_values = *jac->batch_values; Kokkos::deep_copy(batch_x, 0.); PetscInfo(pc, "\tjac->n = %" PetscInt_FMT ", Nloc = %d, Nsolves = %d, nnz = %d, Nsolves_team = %d, league size = %d, maxit = %" PetscInt_FMT "\n", jac->n, Nloc, Nsolves, nnz, Nsolves_team, Nsolves / Nsolves_team, maxit); Kokkos::parallel_for( "rowOffsets+map", Kokkos::TeamPolicy<>(Nsolves, team_size, PCBJKOKKOS_VEC_SIZE), KOKKOS_LAMBDA(const team_member team) { const int blkID = team.league_rank(), start = d_bid_eqOffset[blkID], end = d_bid_eqOffset[blkID + 1]; if (fill_idx) { if (blkID % Nsolves_team == 0) { // first matrix on this member Kokkos::parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](const int rowb) { // Nloc int rowa = d_isicol[rowb]; int n = glb_Aai[rowa + 1] - glb_Aai[rowa]; rowOffsets(blkID / Nsolves_team, rowb + 1 - start) = n; // save sizes }); } } // map b into field major space Kokkos::parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](int rowb) { int rowa = d_isicol[rowb]; batch_b(blkID, rowb - start) = glb_bdata[rowa]; }); }); Kokkos::fence(); if (fill_idx) { Kokkos::parallel_for( "prefix sum", Kokkos::TeamPolicy<>(Nsolves / Nsolves_team, 1, 1), KOKKOS_LAMBDA(const team_member team) { const int graphID = team.league_rank(); rowOffsets(graphID, 0) = 0; for (size_t i = 0; i < Nloc; ++i) rowOffsets(graphID, i + 1) += rowOffsets(graphID, i); }); Kokkos::fence(); } Kokkos::parallel_for( "copy matrix", Kokkos::TeamPolicy<>(Nsolves /* /batch_sz */, team_size, PCBJKOKKOS_VEC_SIZE), KOKKOS_LAMBDA(const team_member team) { const int blkID = team.league_rank(), start = d_bid_eqOffset[blkID], end = d_bid_eqOffset[blkID + 1], graphID = blkID / Nsolves_team; Kokkos::parallel_for(Kokkos::TeamThreadRange(team, start, end), [=](const int rowb) { int rowa = d_isicol[rowb]; // global index int n = glb_Aai[rowa + 1] - glb_Aai[rowa]; const PetscInt *aj = glb_Aaj + glb_Aai[rowa]; const PetscScalar *aa = glb_Aaa + glb_Aai[rowa]; Kokkos::parallel_for(Kokkos::ThreadVectorRange(team, n), [=](const int &i) { PetscScalar val = aa[i]; if (fill_idx && blkID % Nsolves_team == 0) colIndices(graphID, rowOffsets(graphID, rowb - start) + i) = d_isrow[aj[i]] - blkID * Nloc; // local" global - block start batch_values(blkID, rowOffsets(graphID, rowb - start) + i) = val; }); }); }); Kokkos::fence(); // setup solver using ScalarType = typename AMatrixValueView::non_const_value_type; using MagnitudeType = typename Kokkos::Details::ArithTraits::mag_type; using NormViewType = Kokkos::View; using Norm2DViewType = Kokkos::View; using Scalar3DViewType = Kokkos::View; using IntViewType = Kokkos::View; using KrylovHandleType = KokkosBatched::KrylovHandle; const int n_iterations = maxit; const int team_size = -1; const int vector_length = -1; const double tol = rtol; const int ortho_strategy = 0; KrylovHandleType handle(Nsolves, Nsolves_team, n_iterations, true); handle.Arnoldi_view = Scalar3DViewType("", Nsolves, n_iterations, Nloc + n_iterations + 3); // solve double time = Functor_TestBatchedTeamVectorGMRES(batch_values, inv_diag, rowOffsets, colIndices, batch_x, batch_b, Nsolves_team, team_size, vector_length, n_iterations, tol, ortho_strategy, 0, handle) .run(pc); Kokkos::fence(); // get data back Kokkos::parallel_for( "map", Kokkos::TeamPolicy<>(Nsolves /* /batch_sz */, team_size, PCBJKOKKOS_VEC_SIZE), KOKKOS_LAMBDA(const team_member team) { const int blkID = team.league_rank(), start = d_bid_eqOffset[blkID], end = d_bid_eqOffset[blkID + 1]; // 0 // map x into Plex/PETSc Kokkos::parallel_for(Kokkos::TeamVectorRange(team, start, end), [=](int rowb) { int rowa = d_isicol[rowb]; glb_xdata[rowa] = batch_x(blkID, rowb - start); }); }); // output assume species major - clone from Kokkos solvers #if PCBJKOKKOS_VERBOSE_LEVEL >= 3 #if PCBJKOKKOS_VERBOSE_LEVEL >= 4 PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "Iterations\n")); #else PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "max iterations per species (gmres) :")); #endif for (PetscInt dmIdx = 0, s = 0, head = 0; dmIdx < jac->num_dms; dmIdx += batch_sz) { for (PetscInt f = 0, idx = head; f < jac->dm_Nf[dmIdx]; f++, s++, idx++) { #if PCBJKOKKOS_VERBOSE_LEVEL >= 4 PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "%2D:", s)); for (int bid = 0; bid < batch_sz; bid++) PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "%3D ", handle.get_iteration_host(idx + bid * jac->dm_Nf[dmIdx]))); PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "\n")); #else int count = 0, ii; for (int bid = 0; bid < batch_sz; bid++) { if ((ii = handle.get_iteration_host(idx + bid * jac->dm_Nf[dmIdx])) > count) count = ii; } PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "%3d", count)); #endif } head += batch_sz * jac->dm_Nf[dmIdx]; } #if PCBJKOKKOS_VERBOSE_LEVEL == 3 PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "\n")); #endif #endif // return error code, get max it PetscInt count = 0, mbid = 0; if (handle.is_converged_host()) { pcreason = PC_NOERROR; if (!jac->max_nits) { for (int blkID = 0; blkID < nBlk; blkID++) { if (handle.get_iteration_host(blkID) > jac->max_nits) { jac->max_nits = handle.get_iteration_host(blkID); mbid = blkID; } } } } else { PetscCall(PetscPrintf(PETSC_COMM_SELF, "There is at least one system that did not converge.")); pcreason = PC_SUBPC_ERROR; } // output - assume species major order for (int blkID = 0; blkID < nBlk; blkID++) { if (jac->reason) { // -pc_bjkokkos_ksp_converged_reason if (jac->batch_target == blkID) { PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), " Linear solve %s in %d iterations, batch %" PetscInt_FMT ", species %" PetscInt_FMT "\n", handle.is_converged_host(blkID) ? "converged" : "diverged", handle.get_iteration_host(blkID), blkID % batch_sz, blkID / batch_sz)); } else if (jac->batch_target == -1 && handle.get_iteration_host(blkID) > count) { jac->max_nits = count = handle.get_iteration_host(blkID); mbid = blkID; } if (!handle.is_converged_host(blkID)) PetscCall(PetscPrintf(PETSC_COMM_SELF, "ERROR species %d, batch %d did not converge with %d iterations\n", (int)(blkID / batch_sz), (int)blkID % batch_sz, handle.get_iteration_host(blkID))); } } if (jac->batch_target == -1 && jac->reason) { PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), " Linear solve %s in %d iteration, batch %" PetscInt_FMT ", specie %" PetscInt_FMT "\n", handle.is_converged_host(mbid) ? "converged" : "diverged", jac->max_nits, mbid % batch_sz, mbid / batch_sz)); } #if defined(PETSC_HAVE_CUDA) nvtxRangePop(); #endif #else SETERRQ(PetscObjectComm((PetscObject)A), PETSC_ERR_USER, "batch GMRES not supported"); #endif } else { // Kokkos Krylov using scr_mem_t = Kokkos::DefaultExecutionSpace::scratch_memory_space; using vect2D_scr_t = Kokkos::View; Kokkos::View d_metadata("solver meta data", nBlk); int stride_shared, stride_global, global_buff_words; d_bid_eqOffset = jac->d_bid_eqOffset_k->data(); // solve each block independently int scr_bytes_team_shared = 0, nShareVec = 0, nGlobBVec = 0; if (jac->const_block_size) { // use shared memory for work vectors only if constant block size - todo: test efficiency loss int maximum_shared_mem_size = 64000; PetscDevice device; PetscCall(PetscDeviceGetDefault_Internal(&device)); PetscCall(PetscDeviceGetAttribute(device, PETSC_DEVICE_ATTR_SIZE_T_SHARED_MEM_PER_BLOCK, &maximum_shared_mem_size)); stride_shared = jac->const_block_size; // captured nShareVec = maximum_shared_mem_size / (jac->const_block_size * sizeof(PetscScalar)); // integer floor, number of vectors that fit in shared if (nShareVec > nwork) nShareVec = nwork; else nGlobBVec = nwork - nShareVec; global_buff_words = jac->n * nGlobBVec; scr_bytes_team_shared = jac->const_block_size * nShareVec * sizeof(PetscScalar); //PetscCall(PetscPrintf(PETSC_COMM_WORLD,"maximum_shared_mem_size=%d scr_bytes_shared=%d nShareVec=%d, nGlobBVec=%d vec size=%d jac->const_block_size=%d\n",maximum_shared_mem_size,scr_bytes_team_shared,nShareVec,nGlobBVec,jac->const_block_size*sizeof(PetscScalar),jac->const_block_size)); } else { scr_bytes_team_shared = 0; stride_shared = 0; global_buff_words = jac->n * nwork; nGlobBVec = nwork; // not needed == fix } stride_global = jac->n; // captured #if defined(PETSC_HAVE_CUDA) nvtxRangePushA("batch-kokkos-solve"); #endif Kokkos::View d_work_vecs_k("workvectors", global_buff_words); // global work vectors PetscInfo(pc, "\tn = %d. %d shared bytes/team, %d global mem bytes, rtol=%e, num blocks %d, team_size=%d, %d vector threads, %d shared vectors, %d global vectors\n", (int)jac->n, scr_bytes_team_shared, global_buff_words, rtol, (int)nBlk, (int)team_size, PCBJKOKKOS_VEC_SIZE, nShareVec, nGlobBVec); PetscScalar *d_work_vecs = d_work_vecs_k.data(); Kokkos::parallel_for( "Solve", Kokkos::TeamPolicy>(nBlk, team_size, PCBJKOKKOS_VEC_SIZE).set_scratch_size(PCBJKOKKOS_SHARED_LEVEL, Kokkos::PerTeam(scr_bytes_team_shared)), KOKKOS_LAMBDA(const team_member team) { const int blkID = team.league_rank(), start = d_bid_eqOffset[blkID], end = d_bid_eqOffset[blkID + 1]; vect2D_scr_t work_vecs_shared(team.team_scratch(PCBJKOKKOS_SHARED_LEVEL), end - start, nShareVec); PetscScalar *work_buff_shared = work_vecs_shared.data(); PetscScalar *work_buff_global = &d_work_vecs[start]; // start inc'ed in bool print = monitor && (blkID == view_bid); switch (ksp_type_idx) { case BATCH_KSP_BICG_IDX: BJSolve_BICG(team, glb_Aai, glb_Aaj, glb_Aaa, d_isrow, d_isicol, work_buff_global, stride_global, nShareVec, work_buff_shared, stride_shared, rtol, atol, dtol, maxit, &d_metadata[blkID], start, end, glb_idiag, glb_bdata, glb_xdata, print); break; case BATCH_KSP_TFQMR_IDX: BJSolve_TFQMR(team, glb_Aai, glb_Aaj, glb_Aaa, d_isrow, d_isicol, work_buff_global, stride_global, nShareVec, work_buff_shared, stride_shared, rtol, atol, dtol, maxit, &d_metadata[blkID], start, end, glb_idiag, glb_bdata, glb_xdata, print); break; case BATCH_KSP_GMRES_IDX: //BJSolve_GMRES(); break; default: #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) printf("Unknown KSP type %d\n", ksp_type_idx); #else /* void */; #endif } }); Kokkos::fence(); #if defined(PETSC_HAVE_CUDA) nvtxRangePop(); nvtxRangePushA("Post-solve-metadata"); #endif auto h_metadata = Kokkos::create_mirror(Kokkos::HostSpace::memory_space(), d_metadata); Kokkos::deep_copy(h_metadata, d_metadata); #if PCBJKOKKOS_VERBOSE_LEVEL >= 3 #if PCBJKOKKOS_VERBOSE_LEVEL >= 4 PetscCall(PetscPrintf(PETSC_COMM_WORLD, "Iterations\n")); #endif // assume species major #if PCBJKOKKOS_VERBOSE_LEVEL < 4 PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "max iterations per species (%s) :", ksp_type_idx == BATCH_KSP_BICG_IDX ? "bicg" : "tfqmr")); #endif for (PetscInt dmIdx = 0, s = 0, head = 0; dmIdx < jac->num_dms; dmIdx += batch_sz) { for (PetscInt f = 0, idx = head; f < jac->dm_Nf[dmIdx]; f++, s++, idx++) { #if PCBJKOKKOS_VERBOSE_LEVEL >= 4 PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "%2" PetscInt_FMT ":", s)); for (int bid = 0; bid < batch_sz; bid++) PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "%3" PetscInt_FMT " ", h_metadata[idx + bid * jac->dm_Nf[dmIdx]].its)); PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "\n")); #else PetscInt count = 0; for (int bid = 0; bid < batch_sz; bid++) { if (h_metadata[idx + bid * jac->dm_Nf[dmIdx]].its > count) count = h_metadata[idx + bid * jac->dm_Nf[dmIdx]].its; } PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "%3" PetscInt_FMT " ", count)); #endif } head += batch_sz * jac->dm_Nf[dmIdx]; } #if PCBJKOKKOS_VERBOSE_LEVEL == 3 PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), "\n")); #endif #endif PetscInt count = 0, mbid = 0; for (int blkID = 0; blkID < nBlk; blkID++) { PetscCall(PetscLogGpuFlops((PetscLogDouble)h_metadata[blkID].flops)); if (jac->reason) { // -pc_bjkokkos_ksp_converged_reason if (jac->batch_target == blkID) { PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), " Linear solve converged due to %s iterations %d, batch %" PetscInt_FMT ", species %" PetscInt_FMT "\n", KSPConvergedReasons[h_metadata[blkID].reason], h_metadata[blkID].its, blkID % batch_sz, blkID / batch_sz)); } else if (jac->batch_target == -1 && h_metadata[blkID].its > count) { jac->max_nits = count = h_metadata[blkID].its; mbid = blkID; } if (h_metadata[blkID].reason < 0) { PetscCall(PetscPrintf(PETSC_COMM_SELF, "ERROR reason=%s, its=%" PetscInt_FMT ". species %" PetscInt_FMT ", batch %" PetscInt_FMT "\n", KSPConvergedReasons[h_metadata[blkID].reason], h_metadata[blkID].its, blkID / batch_sz, blkID % batch_sz)); } } } if (jac->batch_target == -1 && jac->reason) { PetscCall(PetscPrintf(PetscObjectComm((PetscObject)A), " Linear solve converged due to %s iterations %d, batch %" PetscInt_FMT ", specie %" PetscInt_FMT "\n", KSPConvergedReasons[h_metadata[mbid].reason], h_metadata[mbid].its, mbid % batch_sz, mbid / batch_sz)); } { int errsum; Kokkos::parallel_reduce( nBlk, KOKKOS_LAMBDA(const int idx, int &lsum) { if (d_metadata[idx].reason < 0) ++lsum; }, errsum); pcreason = errsum ? PC_SUBPC_ERROR : PC_NOERROR; if (!errsum && !jac->max_nits) { // set max its to give back to top KSP for (int blkID = 0; blkID < nBlk; blkID++) { if (h_metadata[blkID].its > jac->max_nits) jac->max_nits = h_metadata[blkID].its; } } else if (errsum) { PetscCall(PetscPrintf(PETSC_COMM_SELF, "ERROR Kokkos batch solver did not converge in all solves\n")); } } #if defined(PETSC_HAVE_CUDA) nvtxRangePop(); #endif } // end of Kokkos (not Kernels) solvers block PetscCall(VecRestoreArrayAndMemType(xout, &glb_xdata)); PetscCall(VecRestoreArrayReadAndMemType(bvec, &glb_bdata)); PetscCall(PCSetFailedReason(pc, pcreason)); // map back to Plex space - not used if (plex_batch) { PetscCall(VecCopy(xout, bvec)); PetscCall(VecScatterBegin(plex_batch, bvec, xout, INSERT_VALUES, SCATTER_REVERSE)); PetscCall(VecScatterEnd(plex_batch, bvec, xout, INSERT_VALUES, SCATTER_REVERSE)); PetscCall(VecDestroy(&bvec)); } } // whole 'have aijkok' block PetscFunctionReturn(0); } static PetscErrorCode PCSetUp_BJKOKKOS(PC pc) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; Mat A = pc->pmat; Mat_SeqAIJKokkos *aijkok; PetscBool flg; PetscFunctionBegin; PetscCheck(!pc->useAmat, PetscObjectComm((PetscObject)pc), PETSC_ERR_SUP, "No support for using 'use_amat'"); PetscCheck(A, PetscObjectComm((PetscObject)A), PETSC_ERR_USER, "No matrix - A is used above"); PetscCall(PetscObjectTypeCompareAny((PetscObject)A, &flg, MATSEQAIJKOKKOS, MATMPIAIJKOKKOS, MATAIJKOKKOS, "")); PetscCheck(flg, PetscObjectComm((PetscObject)A), PETSC_ERR_ARG_WRONG, "must use '-dm_mat_type aijkokkos -dm_vec_type kokkos' for -pc_type bjkokkos"); PetscCheck((aijkok = static_cast(A->spptr)), PetscObjectComm((PetscObject)A), PETSC_ERR_USER, "No aijkok"); { if (!jac->vec_diag) { Vec *subX; DM pack, *subDM; PetscInt nDMs, n; PetscContainer container; PetscCall(PetscObjectQuery((PetscObject)A, "plex_batch_is", (PetscObject *)&container)); { // Permute the matrix to get a block diagonal system: d_isrow_k, d_isicol_k MatOrderingType rtype; IS isrow, isicol; const PetscInt *rowindices, *icolindices; rtype = MATORDERINGRCM; // get permutation. Not what I expect so inverted here PetscCall(MatGetOrdering(A, rtype, &isrow, &isicol)); PetscCall(ISDestroy(&isrow)); PetscCall(ISInvertPermutation(isicol, PETSC_DECIDE, &isrow)); // THIS IS BACKWARD -- isrow is inverse -- FIX!!!!! Mat mat_block_order; PetscCall(MatCreateSubMatrix(A, isicol, isicol, MAT_INITIAL_MATRIX, &mat_block_order)); PetscCall(MatViewFromOptions(mat_block_order, NULL, "-ksp_batch_reorder_view")); PetscCall(MatDestroy(&mat_block_order)); PetscCall(ISGetIndices(isrow, &rowindices)); PetscCall(ISGetIndices(isicol, &icolindices)); const Kokkos::View> h_isrow_k((PetscInt *)rowindices, A->rmap->n); const Kokkos::View> h_isicol_k((PetscInt *)icolindices, A->rmap->n); jac->d_isrow_k = new Kokkos::View(Kokkos::create_mirror(DefaultMemorySpace(), h_isrow_k)); jac->d_isicol_k = new Kokkos::View(Kokkos::create_mirror(DefaultMemorySpace(), h_isicol_k)); Kokkos::deep_copy(*jac->d_isrow_k, h_isrow_k); Kokkos::deep_copy(*jac->d_isicol_k, h_isicol_k); PetscCall(ISRestoreIndices(isrow, &rowindices)); PetscCall(ISRestoreIndices(isicol, &icolindices)); PetscCall(ISDestroy(&isrow)); PetscCall(ISDestroy(&isicol)); } // get block sizes PetscCall(PCGetDM(pc, &pack)); PetscCheck(pack, PetscObjectComm((PetscObject)A), PETSC_ERR_USER, "no DM. Requires a composite DM"); PetscCall(PetscObjectTypeCompare((PetscObject)pack, DMCOMPOSITE, &flg)); PetscCheck(flg, PetscObjectComm((PetscObject)pack), PETSC_ERR_USER, "Not for type %s", ((PetscObject)pack)->type_name); PetscCall(DMCompositeGetNumberDM(pack, &nDMs)); jac->num_dms = nDMs; PetscCall(DMCreateGlobalVector(pack, &jac->vec_diag)); PetscCall(VecGetLocalSize(jac->vec_diag, &n)); jac->n = n; jac->d_idiag_k = new Kokkos::View("idiag", n); // options PetscCall(PCBJKOKKOSCreateKSP_BJKOKKOS(pc)); PetscCall(KSPSetFromOptions(jac->ksp)); PetscCall(PetscObjectTypeCompareAny((PetscObject)jac->ksp, &flg, KSPBICG, "")); if (flg) { jac->ksp_type_idx = BATCH_KSP_BICG_IDX; jac->nwork = 7; } else { PetscCall(PetscObjectTypeCompareAny((PetscObject)jac->ksp, &flg, KSPTFQMR, "")); if (flg) { jac->ksp_type_idx = BATCH_KSP_TFQMR_IDX; jac->nwork = 10; } else { PetscCall(PetscObjectTypeCompareAny((PetscObject)jac->ksp, &flg, KSPGMRES, "")); PetscCheck(flg, PetscObjectComm((PetscObject)A), PETSC_ERR_ARG_WRONG, "Unsupported batch ksp type"); jac->ksp_type_idx = BATCH_KSP_GMRES_IDX; jac->nwork = 0; } } PetscOptionsBegin(PetscObjectComm((PetscObject)jac->ksp), ((PetscObject)jac->ksp)->prefix, "Options for Kokkos batch solver", "none"); PetscCall(PetscOptionsBool("-ksp_converged_reason", "", "bjkokkos.kokkos.cxx.c", jac->reason, &jac->reason, NULL)); PetscCall(PetscOptionsBool("-ksp_monitor", "", "bjkokkos.kokkos.cxx.c", jac->monitor, &jac->monitor, NULL)); PetscCall(PetscOptionsInt("-ksp_batch_target", "", "bjkokkos.kokkos.cxx.c", jac->batch_target, &jac->batch_target, NULL)); PetscCall(PetscOptionsInt("-ksp_batch_nsolves_team", "", "bjkokkos.kokkos.cxx.c", jac->nsolves_team, &jac->nsolves_team, NULL)); PetscCheck(jac->batch_target < jac->num_dms, PETSC_COMM_WORLD, PETSC_ERR_ARG_WRONG, "-ksp_batch_target (%" PetscInt_FMT ") >= number of DMs (%" PetscInt_FMT ")", jac->batch_target, jac->num_dms); PetscOptionsEnd(); // get blocks - jac->d_bid_eqOffset_k PetscCall(PetscMalloc(sizeof(*subX) * nDMs, &subX)); PetscCall(PetscMalloc(sizeof(*subDM) * nDMs, &subDM)); PetscCall(PetscMalloc(sizeof(*jac->dm_Nf) * nDMs, &jac->dm_Nf)); PetscCall(PetscInfo(pc, "Have %" PetscInt_FMT " DMs, n=%" PetscInt_FMT " rtol=%g type = %s\n", nDMs, n, (double)jac->ksp->rtol, ((PetscObject)jac->ksp)->type_name)); PetscCall(DMCompositeGetEntriesArray(pack, subDM)); jac->nBlocks = 0; for (PetscInt ii = 0; ii < nDMs; ii++) { PetscSection section; PetscInt Nf; DM dm = subDM[ii]; PetscCall(DMGetLocalSection(dm, §ion)); PetscCall(PetscSectionGetNumFields(section, &Nf)); jac->nBlocks += Nf; #if PCBJKOKKOS_VERBOSE_LEVEL <= 2 if (ii == 0) PetscCall(PetscInfo(pc, "%" PetscInt_FMT ") %" PetscInt_FMT " blocks (%" PetscInt_FMT " total)\n", ii, Nf, jac->nBlocks)); #else PetscCall(PetscInfo(pc, "%" PetscInt_FMT ") %" PetscInt_FMT " blocks (%" PetscInt_FMT " total)\n", ii, Nf, jac->nBlocks)); #endif jac->dm_Nf[ii] = Nf; } { // d_bid_eqOffset_k Kokkos::View h_block_offsets("block_offsets", jac->nBlocks + 1); PetscCall(DMCompositeGetAccessArray(pack, jac->vec_diag, nDMs, NULL, subX)); h_block_offsets[0] = 0; jac->const_block_size = -1; for (PetscInt ii = 0, idx = 0; ii < nDMs; ii++) { PetscInt nloc, nblk; PetscCall(VecGetSize(subX[ii], &nloc)); nblk = nloc / jac->dm_Nf[ii]; PetscCheck(nloc % jac->dm_Nf[ii] == 0, PetscObjectComm((PetscObject)pc), PETSC_ERR_USER, "nloc%%jac->dm_Nf[ii] (%" PetscInt_FMT ") != 0 DMs", nloc % jac->dm_Nf[ii]); for (PetscInt jj = 0; jj < jac->dm_Nf[ii]; jj++, idx++) { h_block_offsets[idx + 1] = h_block_offsets[idx] + nblk; #if PCBJKOKKOS_VERBOSE_LEVEL <= 2 if (idx == 0) PetscCall(PetscInfo(pc, "\t%" PetscInt_FMT ") Add block with %" PetscInt_FMT " equations of %" PetscInt_FMT "\n", idx + 1, nblk, jac->nBlocks)); #else PetscCall(PetscInfo(pc, "\t%" PetscInt_FMT ") Add block with %" PetscInt_FMT " equations of %" PetscInt_FMT "\n", idx + 1, nblk, jac->nBlocks)); #endif if (jac->const_block_size == -1) jac->const_block_size = nblk; else if (jac->const_block_size > 0 && jac->const_block_size != nblk) jac->const_block_size = 0; } } PetscCall(DMCompositeRestoreAccessArray(pack, jac->vec_diag, jac->nBlocks, NULL, subX)); PetscCall(PetscFree(subX)); PetscCall(PetscFree(subDM)); jac->d_bid_eqOffset_k = new Kokkos::View(Kokkos::create_mirror(Kokkos::DefaultExecutionSpace::memory_space(), h_block_offsets)); Kokkos::deep_copy(*jac->d_bid_eqOffset_k, h_block_offsets); } } { // get jac->d_idiag_k (PC setup), const PetscInt *d_ai = aijkok->i_device_data(), *d_aj = aijkok->j_device_data(); const PetscScalar *d_aa = aijkok->a_device_data(); const PetscInt conc = Kokkos::DefaultExecutionSpace().concurrency(), openmp = !!(conc < 1000), team_size = (openmp == 0 && PCBJKOKKOS_VEC_SIZE != 1) ? PCBJKOKKOS_TEAM_SIZE : 1; PetscInt *d_bid_eqOffset = jac->d_bid_eqOffset_k->data(), *r = jac->d_isrow_k->data(), *ic = jac->d_isicol_k->data(); PetscScalar *d_idiag = jac->d_idiag_k->data(); Kokkos::parallel_for( "Diag", Kokkos::TeamPolicy<>(jac->nBlocks, team_size, PCBJKOKKOS_VEC_SIZE), KOKKOS_LAMBDA(const team_member team) { const PetscInt blkID = team.league_rank(); Kokkos::parallel_for(Kokkos::TeamThreadRange(team, d_bid_eqOffset[blkID], d_bid_eqOffset[blkID + 1]), [=](const int rowb) { const PetscInt rowa = ic[rowb], ai = d_ai[rowa], *aj = d_aj + ai; // grab original data const PetscScalar *aa = d_aa + ai; const PetscInt nrow = d_ai[rowa + 1] - ai; int found; Kokkos::parallel_reduce( Kokkos::ThreadVectorRange(team, nrow), [=](const int &j, int &count) { const PetscInt colb = r[aj[j]]; if (colb == rowb) { d_idiag[rowb] = 1. / aa[j]; count++; } }, found); #if defined(PETSC_USE_DEBUG) && !defined(PETSC_HAVE_SYCL) if (found != 1) Kokkos::single(Kokkos::PerThread(team), [=]() { printf("ERRORrow %d) found = %d\n", rowb, found); }); #endif }); }); } } PetscFunctionReturn(0); } /* Default destroy, if it has never been setup */ static PetscErrorCode PCReset_BJKOKKOS(PC pc) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; PetscFunctionBegin; PetscCall(KSPDestroy(&jac->ksp)); PetscCall(VecDestroy(&jac->vec_diag)); if (jac->d_bid_eqOffset_k) delete jac->d_bid_eqOffset_k; if (jac->d_idiag_k) delete jac->d_idiag_k; if (jac->d_isrow_k) delete jac->d_isrow_k; if (jac->d_isicol_k) delete jac->d_isicol_k; jac->d_bid_eqOffset_k = NULL; jac->d_idiag_k = NULL; jac->d_isrow_k = NULL; jac->d_isicol_k = NULL; PetscCall(PetscObjectComposeFunction((PetscObject)pc, "PCBJKOKKOSGetKSP_C", NULL)); // not published now (causes configure errors) PetscCall(PetscObjectComposeFunction((PetscObject)pc, "PCBJKOKKOSSetKSP_C", NULL)); PetscCall(PetscFree(jac->dm_Nf)); jac->dm_Nf = NULL; if (jac->rowOffsets) delete jac->rowOffsets; if (jac->colIndices) delete jac->colIndices; if (jac->batch_b) delete jac->batch_b; if (jac->batch_x) delete jac->batch_x; if (jac->batch_values) delete jac->batch_values; jac->rowOffsets = NULL; jac->colIndices = NULL; jac->batch_b = NULL; jac->batch_x = NULL; jac->batch_values = NULL; PetscFunctionReturn(0); } static PetscErrorCode PCDestroy_BJKOKKOS(PC pc) { PetscFunctionBegin; PetscCall(PCReset_BJKOKKOS(pc)); PetscCall(PetscFree(pc->data)); PetscFunctionReturn(0); } static PetscErrorCode PCView_BJKOKKOS(PC pc, PetscViewer viewer) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; PetscBool iascii; PetscFunctionBegin; if (!jac->ksp) PetscCall(PCBJKOKKOSCreateKSP_BJKOKKOS(pc)); PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERASCII, &iascii)); if (iascii) { PetscCall(PetscViewerASCIIPrintf(viewer, " Batched device linear solver: Krylov (KSP) method with Jacobi preconditioning\n")); PetscCall(PetscViewerASCIIPrintf(viewer, "\t\tnwork = %" PetscInt_FMT ", rel tol = %e, abs tol = %e, div tol = %e, max it =%" PetscInt_FMT ", type = %s\n", jac->nwork, jac->ksp->rtol, jac->ksp->abstol, jac->ksp->divtol, jac->ksp->max_it, ((PetscObject)jac->ksp)->type_name)); } PetscFunctionReturn(0); } static PetscErrorCode PCSetFromOptions_BJKOKKOS(PC pc, PetscOptionItems *PetscOptionsObject) { PetscFunctionBegin; PetscOptionsHeadBegin(PetscOptionsObject, "PC BJKOKKOS options"); PetscOptionsHeadEnd(); PetscFunctionReturn(0); } static PetscErrorCode PCBJKOKKOSSetKSP_BJKOKKOS(PC pc, KSP ksp) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; PetscFunctionBegin; PetscCall(PetscObjectReference((PetscObject)ksp)); PetscCall(KSPDestroy(&jac->ksp)); jac->ksp = ksp; PetscFunctionReturn(0); } /*@C PCBJKOKKOSSetKSP - Sets the `KSP` context for `PCBJKOKKOS` Collective Input Parameters: + pc - the `PCBJKOKKOS` preconditioner context - ksp - the `KSP` solver Notes: The `PC` and the `KSP` must have the same communicator If the `PC` is not `PCBJKOKKOS` this function returns without doing anything Level: advanced ,seealso: `PCBJKOKKOSGetKSP()`, `PCBJKOKKOS` @*/ PetscErrorCode PCBJKOKKOSSetKSP(PC pc, KSP ksp) { PetscFunctionBegin; PetscValidHeaderSpecific(pc, PC_CLASSID, 1); PetscValidHeaderSpecific(ksp, KSP_CLASSID, 2); PetscCheckSameComm(pc, 1, ksp, 2); PetscTryMethod(pc, "PCBJKOKKOSSetKSP_C", (PC, KSP), (pc, ksp)); PetscFunctionReturn(0); } static PetscErrorCode PCBJKOKKOSGetKSP_BJKOKKOS(PC pc, KSP *ksp) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; PetscFunctionBegin; if (!jac->ksp) PetscCall(PCBJKOKKOSCreateKSP_BJKOKKOS(pc)); *ksp = jac->ksp; PetscFunctionReturn(0); } /*@C PCBJKOKKOSGetKSP - Gets the `KSP` context for the `PCBJKOKKOS` preconditioner Not Collective but `KSP` returned is parallel if `PC` was parallel Input Parameter: . pc - the preconditioner context Output Parameter: . ksp - the `KSP` solver Notes: You must call `KSPSetUp()` before calling `PCBJKOKKOSGetKSP()`. If the `PC` is not a `PCBJKOKKOS` object it raises an error Level: advanced .seealso: `PCBJKOKKOS`, `PCBJKOKKOSSetKSP()` @*/ PetscErrorCode PCBJKOKKOSGetKSP(PC pc, KSP *ksp) { PetscFunctionBegin; PetscValidHeaderSpecific(pc, PC_CLASSID, 1); PetscValidPointer(ksp, 2); PetscUseMethod(pc, "PCBJKOKKOSGetKSP_C", (PC, KSP *), (pc, ksp)); PetscFunctionReturn(0); } static PetscErrorCode PCPostSolve_BJKOKKOS(PC pc, KSP ksp, Vec b, Vec x) { PC_PCBJKOKKOS *jac = (PC_PCBJKOKKOS *)pc->data; PetscFunctionBegin; ksp->its = jac->max_nits; PetscFunctionReturn(0); } /*MC PCBJKOKKOS - Defines a preconditioner that applies a Krylov solver and preconditioner to the blocks in a `MATSEQAIJ` matrix on the GPU using Kokkos Options Database Key: . -pc_bjkokkos_ - options prefix for its `KSP` options Level: intermediate Note: For use with -ksp_type preonly to bypass any computation on the CPU Developer Notes: The documentation is incomplete. Is this a block Jacobi preconditioner? Why does it have its own `KSP`? Where is the `KSP` run if used with -ksp_type preonly? .seealso: `PCCreate()`, `PCSetType()`, `PCType`, `PC`, `PCBJACOBI`, `PCSHELL`, `PCCOMPOSITE`, `PCSetUseAmat()`, `PCBJKOKKOSGetKSP()` M*/ PETSC_EXTERN PetscErrorCode PCCreate_BJKOKKOS(PC pc) { PC_PCBJKOKKOS *jac; PetscFunctionBegin; PetscCall(PetscNew(&jac)); pc->data = (void *)jac; jac->ksp = NULL; jac->vec_diag = NULL; jac->d_bid_eqOffset_k = NULL; jac->d_idiag_k = NULL; jac->d_isrow_k = NULL; jac->d_isicol_k = NULL; jac->nBlocks = 1; jac->max_nits = 0; PetscCall(PetscMemzero(pc->ops, sizeof(struct _PCOps))); pc->ops->apply = PCApply_BJKOKKOS; pc->ops->applytranspose = NULL; pc->ops->setup = PCSetUp_BJKOKKOS; pc->ops->reset = PCReset_BJKOKKOS; pc->ops->destroy = PCDestroy_BJKOKKOS; pc->ops->setfromoptions = PCSetFromOptions_BJKOKKOS; pc->ops->view = PCView_BJKOKKOS; pc->ops->postsolve = PCPostSolve_BJKOKKOS; jac->rowOffsets = NULL; jac->colIndices = NULL; jac->batch_b = NULL; jac->batch_x = NULL; jac->batch_values = NULL; PetscCall(PetscObjectComposeFunction((PetscObject)pc, "PCBJKOKKOSGetKSP_C", PCBJKOKKOSGetKSP_BJKOKKOS)); PetscCall(PetscObjectComposeFunction((PetscObject)pc, "PCBJKOKKOSSetKSP_C", PCBJKOKKOSSetKSP_BJKOKKOS)); PetscFunctionReturn(0); }