// Copyright (c) 2017, Lawrence Livermore National Security, LLC. Produced at // the Lawrence Livermore National Laboratory. LLNL-CODE-734707. All Rights // reserved. See files LICENSE and NOTICE for details. // // This file is part of CEED, a collection of benchmarks, miniapps, software // libraries and APIs for efficient high-order finite element and spectral // element discretizations for exascale applications. For more information and // source code availability see http://github.com/ceed. // // The CEED research is supported by the Exascale Computing Project 17-SC-20-SC, // a collaborative effort of two U.S. Department of Energy organizations (Office // of Science and the National Nuclear Security Administration) responsible for // the planning and preparation of a capable exascale ecosystem, including // software, applications, hardware, advanced system engineering and early // testbed platforms, in support of the nation's exascale computing imperative. // libCEED + PETSc Example: CEED BPs 3-6 with Multigrid // // This example demonstrates a simple usage of libCEED with PETSc to solve the // CEED BP benchmark problems, see http://ceed.exascaleproject.org/bps. // // The code uses higher level communication protocols in DMPlex. // // Build with: // // make multigrid [PETSC_DIR=] [CEED_DIR=] // // Sample runs: // // multigrid -problem bp3 // multigrid -problem bp4 -ceed /cpu/self // multigrid -problem bp5 -ceed /cpu/occa // multigrid -problem bp6 -ceed /gpu/cuda // //TESTARGS -ceed {ceed_resource} -test -problem bp3 -degree 3 /// @file /// CEED BPs 1-6 multigrid example using PETSc const char help[] = "Solve CEED BPs using p-multigrid with PETSc and DMPlex\n"; #define multigrid #include "setup.h" int main(int argc, char **argv) { PetscInt ierr; MPI_Comm comm; char ceedresource[PETSC_MAX_PATH_LEN] = "/cpu/self", filename[PETSC_MAX_PATH_LEN]; double my_rt_start, my_rt, rt_min, rt_max; PetscInt degree = 3, qextra, *lsize, *xlsize, *gsize, dim = 3, melem[3] = {3, 3, 3}, ncompu = 1, numlevels = degree, *leveldegrees; PetscScalar *r; PetscBool test_mode, benchmark_mode, read_mesh, write_solution; DM *dm, dmOrig; KSP ksp; PC pc; Mat *matO, *matI, *matR; Vec *X, *Xloc, *mult, rhs, rhsloc, diagloc; UserO *userO; UserIR *userI, *userR; Ceed ceed; CeedData *ceeddata; CeedVector rhsceed, diagceed, target; CeedQFunction qf_error, qf_restrict, qf_prolong; CeedOperator op_error; bpType bpChoice; coarsenType coarsen; ierr = PetscInitialize(&argc, &argv, NULL, help); if (ierr) return ierr; comm = PETSC_COMM_WORLD; // Parse command line options ierr = PetscOptionsBegin(comm, NULL, "CEED BPs in PETSc", NULL); CHKERRQ(ierr); bpChoice = CEED_BP3; ierr = PetscOptionsEnum("-problem", "CEED benchmark problem to solve", NULL, bpTypes, (PetscEnum)bpChoice, (PetscEnum *)&bpChoice, NULL); CHKERRQ(ierr); ncompu = bpOptions[bpChoice].ncompu; test_mode = PETSC_FALSE; ierr = PetscOptionsBool("-test", "Testing mode (do not print unless error is large)", NULL, test_mode, &test_mode, NULL); CHKERRQ(ierr); benchmark_mode = PETSC_FALSE; ierr = PetscOptionsBool("-benchmark", "Benchmarking mode (prints benchmark statistics)", NULL, benchmark_mode, &benchmark_mode, NULL); CHKERRQ(ierr); write_solution = PETSC_FALSE; ierr = PetscOptionsBool("-write_solution", "Write solution for visualization", NULL, write_solution, &write_solution, NULL); CHKERRQ(ierr); degree = test_mode ? 3 : 2; ierr = PetscOptionsInt("-degree", "Polynomial degree of tensor product basis", NULL, degree, °ree, NULL); CHKERRQ(ierr); if (degree < 1) SETERRQ1(PETSC_COMM_WORLD, PETSC_ERR_ARG_OUTOFRANGE, "-degree %D must be at least 1", degree); qextra = bpOptions[bpChoice].qextra; ierr = PetscOptionsInt("-qextra", "Number of extra quadrature points", NULL, qextra, &qextra, NULL); CHKERRQ(ierr); ierr = PetscOptionsString("-ceed", "CEED resource specifier", NULL, ceedresource, ceedresource, sizeof(ceedresource), NULL); CHKERRQ(ierr); coarsen = COARSEN_UNIFORM; ierr = PetscOptionsEnum("-coarsen", "Coarsening strategy to use", NULL, coarsenTypes, (PetscEnum)coarsen, (PetscEnum *)&coarsen, NULL); CHKERRQ(ierr); read_mesh = PETSC_FALSE; ierr = PetscOptionsString("-mesh", "Read mesh from file", NULL, filename, filename, sizeof(filename), &read_mesh); CHKERRQ(ierr); if (!read_mesh) { PetscInt tmp = dim; ierr = PetscOptionsIntArray("-cells","Number of cells per dimension", NULL, melem, &tmp, NULL); CHKERRQ(ierr); } ierr = PetscOptionsEnd(); CHKERRQ(ierr); // Setup DM if (read_mesh) { ierr = DMPlexCreateFromFile(PETSC_COMM_WORLD, filename, PETSC_TRUE, &dmOrig); CHKERRQ(ierr); } else { ierr = DMPlexCreateBoxMesh(PETSC_COMM_WORLD, dim, PETSC_FALSE, melem, NULL, NULL, NULL, PETSC_TRUE,&dmOrig); CHKERRQ(ierr); } { DM dmDist = NULL; PetscPartitioner part; ierr = DMPlexGetPartitioner(dmOrig, &part); CHKERRQ(ierr); ierr = PetscPartitionerSetFromOptions(part); CHKERRQ(ierr); ierr = DMPlexDistribute(dmOrig, 0, NULL, &dmDist); CHKERRQ(ierr); if (dmDist) { ierr = DMDestroy(&dmOrig); CHKERRQ(ierr); dmOrig = dmDist; } } // Allocate arrays for PETSc objects for each level switch (coarsen) { case COARSEN_UNIFORM: numlevels = degree; break; case COARSEN_LOGARITHMIC: numlevels = ceil(log(degree)/log(2)) + 1; break; } ierr = PetscMalloc1(numlevels, &leveldegrees); CHKERRQ(ierr); switch (coarsen) { case COARSEN_UNIFORM: for (int i=0; i 0) { // Interp ierr = PetscMalloc1(1, &userI[i]); CHKERRQ(ierr); ierr = MatCreateShell(comm, lsize[i], lsize[i-1], gsize[i], gsize[i-1], userI[i], &matI[i]); CHKERRQ(ierr); ierr = MatShellSetOperation(matI[i], MATOP_MULT, (void(*)(void))MatMult_Interp); CHKERRQ(ierr); // Restrict ierr = PetscMalloc1(1, &userR[i]); CHKERRQ(ierr); ierr = MatCreateShell(comm, lsize[i-1], lsize[i], gsize[i-1], gsize[i], userR[i], &matR[i]); CHKERRQ(ierr); ierr = MatShellSetOperation(matR[i], MATOP_MULT, (void(*)(void))MatMult_Restrict); CHKERRQ(ierr); } } ierr = VecDuplicate(X[numlevels-1], &rhs); CHKERRQ(ierr); // Set up libCEED CeedInit(ceedresource, &ceed); // Print global grid information if (!test_mode) { PetscInt P = degree + 1, Q = P + qextra; const char *usedresource; CeedGetResource(ceed, &usedresource); ierr = PetscPrintf(comm, "\n-- CEED Benchmark Problem %d -- libCEED + PETSc + PCMG --\n" " libCEED:\n" " libCEED Backend : %s\n" " Mesh:\n" " Number of 1D Basis Nodes (p) : %d\n" " Number of 1D Quadrature Points (q) : %d\n" " Global Nodes : %D\n" " Owned Nodes : %D\n" " Multigrid:\n" " Number of Levels : %d\n", bpChoice+1, usedresource, P, Q, gsize[numlevels-1]/ncompu, lsize[numlevels-1]/ncompu, numlevels); CHKERRQ(ierr); } // Create RHS vector ierr = VecDuplicate(Xloc[numlevels-1], &rhsloc); CHKERRQ(ierr); ierr = VecZeroEntries(rhsloc); CHKERRQ(ierr); ierr = VecGetArray(rhsloc, &r); CHKERRQ(ierr); CeedVectorCreate(ceed, xlsize[numlevels-1], &rhsceed); CeedVectorSetArray(rhsceed, CEED_MEM_HOST, CEED_USE_POINTER, r); // Set up libCEED operators on each level ierr = PetscMalloc1(numlevels, &ceeddata); CHKERRQ(ierr); for (int i=0; iErestrictu, CEED_TRANSPOSE, ceeddata[numlevels-1]->basisu, CEED_VECTOR_ACTIVE); CeedOperatorSetField(op_error, "true_soln", ceeddata[numlevels-1]->Erestrictui, CEED_NOTRANSPOSE, CEED_BASIS_COLLOCATED, target); CeedOperatorSetField(op_error, "error", ceeddata[numlevels-1]->Erestrictui, CEED_NOTRANSPOSE, CEED_BASIS_COLLOCATED, CEED_VECTOR_ACTIVE); // Calculate multiplicity for (int i=0; ixceed, CEED_MEM_HOST, CEED_USE_POINTER, x); // Multiplicity CeedElemRestrictionGetMultiplicity(ceeddata[i]->Erestrictu, ceeddata[i]->xceed); // Restore vector ierr = VecRestoreArray(Xloc[i], &x); CHKERRQ(ierr); // Creat mult vector ierr = VecDuplicate(Xloc[i], &mult[i]); CHKERRQ(ierr); // Local-to-global ierr = VecZeroEntries(X[i]); CHKERRQ(ierr); ierr = DMLocalToGlobalBegin(dm[i], Xloc[i], ADD_VALUES, X[i]); CHKERRQ(ierr); ierr = DMLocalToGlobalEnd(dm[i], Xloc[i], ADD_VALUES, X[i]); CHKERRQ(ierr); ierr = VecZeroEntries(Xloc[i]); CHKERRQ(ierr); // Global-to-local ierr = DMGlobalToLocalBegin(dm[i], X[i], INSERT_VALUES, mult[i]); CHKERRQ(ierr); ierr = DMGlobalToLocalEnd(dm[i], X[i], INSERT_VALUES, mult[i]); CHKERRQ(ierr); ierr = VecZeroEntries(X[i]); CHKERRQ(ierr); // Multiplicity scaling ierr = VecReciprocal(mult[i]); } // Set up Mat for (int i=0; icomm = comm; userO[i]->dm = dm[i]; userO[i]->Xloc = Xloc[i]; ierr = VecDuplicate(Xloc[i], &userO[i]->Yloc); CHKERRQ(ierr); userO[i]->xceed = ceeddata[i]->xceed; userO[i]->yceed = ceeddata[i]->yceed; userO[i]->op = ceeddata[i]->op_apply; userO[i]->ceed = ceed; // Set up diagonal const CeedScalar *ceedarray; PetscScalar *petscarray; CeedInt length; ierr = VecDuplicate(X[i], &userO[i]->diag); CHKERRQ(ierr); ierr = VecDuplicate(Xloc[i], &diagloc); CHKERRQ(ierr); // -- Local diagonal CeedOperatorAssembleLinearDiagonal(userO[i]->op, &diagceed, CEED_REQUEST_IMMEDIATE); // -- Copy values CeedVectorGetArrayRead(diagceed, CEED_MEM_HOST, &ceedarray); ierr = VecGetArray(diagloc, &petscarray); CHKERRQ(ierr); CeedVectorGetLength(diagceed, &length); for (CeedInt i=0; idiag); CHKERRQ(ierr); ierr = DMLocalToGlobalBegin(userO[i]->dm, diagloc, ADD_VALUES, userO[i]->diag); CHKERRQ(ierr); ierr = DMLocalToGlobalEnd(userO[i]->dm, diagloc, ADD_VALUES, userO[i]->diag); CHKERRQ(ierr); // -- Cleanup ierr = VecDestroy(&diagloc); CHKERRQ(ierr); CeedVectorDestroy(&diagceed); if (i > 0) { // Interp Operator userI[i]->comm = comm; userI[i]->dmc = dm[i-1]; userI[i]->dmf = dm[i]; userI[i]->Xloc = Xloc[i-1]; userI[i]->Yloc = userO[i]->Yloc; userI[i]->mult = mult[i]; userI[i]->ceedvecc = userO[i-1]->xceed; userI[i]->ceedvecf = userO[i]->yceed; userI[i]->op = ceeddata[i]->op_interp; userI[i]->ceed = ceed; // Restrict Operator userR[i]->comm = comm; userR[i]->dmc = dm[i-1]; userR[i]->dmf = dm[i]; userR[i]->Xloc = Xloc[i]; userR[i]->Yloc = userO[i-1]->Yloc; userR[i]->mult = mult[i]; userR[i]->ceedvecf = userO[i]->xceed; userR[i]->ceedvecc = userO[i-1]->yceed; userR[i]->op = ceeddata[i]->op_restrict; userR[i]->ceed = ceed; } } // Set up KSP ierr = KSPCreate(comm, &ksp); CHKERRQ(ierr); { ierr = KSPSetType(ksp, KSPCG); CHKERRQ(ierr); ierr = KSPSetNormType(ksp, KSP_NORM_NATURAL); CHKERRQ(ierr); ierr = KSPSetTolerances(ksp, 1e-10, PETSC_DEFAULT, PETSC_DEFAULT, PETSC_DEFAULT); CHKERRQ(ierr); } ierr = KSPSetFromOptions(ksp); CHKERRQ(ierr); ierr = KSPSetOperators(ksp, matO[numlevels-1], matO[numlevels-1]); CHKERRQ(ierr); // Set up PCMG ierr = KSPGetPC(ksp, &pc); CHKERRQ(ierr); PCMGCycleType pcgmcycletype = PC_MG_CYCLE_V; { ierr = PCSetType(pc, PCMG); CHKERRQ(ierr); // PCMG levels ierr = PCMGSetLevels(pc, numlevels, NULL); CHKERRQ(ierr); for (int i=0; i 0) { // Interpolation ierr = PCMGSetInterpolation(pc, i, matI[i]); CHKERRQ(ierr); // Restriction ierr = PCMGSetRestriction(pc, i, matR[i]); CHKERRQ(ierr); } // Coarse solve KSP coarse; PC coarse_pc; ierr = PCMGGetCoarseSolve(pc, &coarse); CHKERRQ(ierr); ierr = KSPSetType(coarse, KSPCG); CHKERRQ(ierr); ierr = KSPSetOperators(coarse, matO[0], matO[0]); CHKERRQ(ierr); ierr = KSPSetTolerances(coarse, 1e-10, 1e-10, PETSC_DEFAULT, PETSC_DEFAULT); CHKERRQ(ierr); ierr = KSPGetPC(coarse, &coarse_pc); CHKERRQ(ierr); ierr = PCSetType(coarse_pc, PCJACOBI); CHKERRQ(ierr); ierr = PCJacobiSetType(coarse_pc, PC_JACOBI_DIAGONAL); CHKERRQ(ierr); } // PCMG options ierr = PCMGSetType(pc, PC_MG_MULTIPLICATIVE); CHKERRQ(ierr); ierr = PCMGSetNumberSmooth(pc, 3); CHKERRQ(ierr); ierr = PCMGSetCycleType(pc, pcgmcycletype); CHKERRQ(ierr); } // First run, if benchmarking if (benchmark_mode) { ierr = KSPSetTolerances(ksp, 1e-10, PETSC_DEFAULT, PETSC_DEFAULT, 1); CHKERRQ(ierr); ierr = VecZeroEntries(X[numlevels-1]); CHKERRQ(ierr); my_rt_start = MPI_Wtime(); ierr = KSPSolve(ksp, rhs, X[numlevels-1]); CHKERRQ(ierr); my_rt = MPI_Wtime() - my_rt_start; ierr = MPI_Allreduce(MPI_IN_PLACE, &my_rt, 1, MPI_DOUBLE, MPI_MIN, comm); CHKERRQ(ierr); // Set maxits based on first iteration timing if (my_rt > 0.02) { ierr = KSPSetTolerances(ksp, 1e-10, PETSC_DEFAULT, PETSC_DEFAULT, 5); CHKERRQ(ierr); } else { ierr = KSPSetTolerances(ksp, 1e-10, PETSC_DEFAULT, PETSC_DEFAULT, 20); CHKERRQ(ierr); } } // Timed solve ierr = VecZeroEntries(X[numlevels-1]); CHKERRQ(ierr); ierr = PetscBarrier((PetscObject)ksp); CHKERRQ(ierr); my_rt_start = MPI_Wtime(); ierr = KSPSolve(ksp, rhs, X[numlevels-1]); CHKERRQ(ierr); my_rt = MPI_Wtime() - my_rt_start; // Output results { KSPType ksptype; PCMGType pcmgtype; KSPConvergedReason reason; PetscReal rnorm; PetscInt its; ierr = KSPGetType(ksp, &ksptype); CHKERRQ(ierr); ierr = KSPGetConvergedReason(ksp, &reason); CHKERRQ(ierr); ierr = KSPGetIterationNumber(ksp, &its); CHKERRQ(ierr); ierr = KSPGetResidualNorm(ksp, &rnorm); CHKERRQ(ierr); ierr = PCMGGetType(pc, &pcmgtype); CHKERRQ(ierr); if (!test_mode || reason < 0 || rnorm > 1e-8) { ierr = PetscPrintf(comm, " KSP:\n" " KSP Type : %s\n" " KSP Convergence : %s\n" " Total KSP Iterations : %D\n" " Final rnorm : %e\n", ksptype, KSPConvergedReasons[reason], its, (double)rnorm); CHKERRQ(ierr); ierr = PetscPrintf(comm, " PCMG:\n" " PCMG Type : %s\n" " PCMG Cycle Type : %s\n", PCMGTypes[pcmgtype], PCMGCycleTypes[pcgmcycletype]); CHKERRQ(ierr); } if (!test_mode) { ierr = PetscPrintf(comm," Performance:\n"); CHKERRQ(ierr); } { PetscReal maxerror; ierr = ComputeErrorMax(userO[numlevels-1], op_error, X[numlevels-1], target, &maxerror); CHKERRQ(ierr); PetscReal tol = 5e-2; if (!test_mode || maxerror > tol) { ierr = MPI_Allreduce(&my_rt, &rt_min, 1, MPI_DOUBLE, MPI_MIN, comm); CHKERRQ(ierr); ierr = MPI_Allreduce(&my_rt, &rt_max, 1, MPI_DOUBLE, MPI_MAX, comm); CHKERRQ(ierr); ierr = PetscPrintf(comm, " Pointwise Error (max) : %e\n" " CG Solve Time : %g (%g) sec\n", (double)maxerror, rt_max, rt_min); CHKERRQ(ierr); } } if (benchmark_mode && (!test_mode)) { ierr = PetscPrintf(comm, " DoFs/Sec in CG : %g (%g) million\n", 1e-6*gsize[numlevels-1]*its/rt_max, 1e-6*gsize[numlevels-1]*its/rt_min); CHKERRQ(ierr); } } if (write_solution) { PetscViewer vtkviewersoln; ierr = PetscViewerCreate(comm, &vtkviewersoln); CHKERRQ(ierr); ierr = PetscViewerSetType(vtkviewersoln, PETSCVIEWERVTK); CHKERRQ(ierr); ierr = PetscViewerFileSetName(vtkviewersoln, "solution.vtk"); CHKERRQ(ierr); ierr = VecView(X[numlevels-1], vtkviewersoln); CHKERRQ(ierr); ierr = PetscViewerDestroy(&vtkviewersoln); CHKERRQ(ierr); } // Cleanup for (int i=0; iYloc); CHKERRQ(ierr); ierr = VecDestroy(&userO[i]->diag); CHKERRQ(ierr); ierr = MatDestroy(&matO[i]); CHKERRQ(ierr); ierr = PetscFree(userO[i]); CHKERRQ(ierr); if (i > 0) { ierr = MatDestroy(&matI[i]); CHKERRQ(ierr); ierr = PetscFree(userI[i]); CHKERRQ(ierr); ierr = MatDestroy(&matR[i]); CHKERRQ(ierr); ierr = PetscFree(userR[i]); CHKERRQ(ierr); } ierr = CeedDataDestroy(i, ceeddata[i]); CHKERRQ(ierr); ierr = DMDestroy(&dm[i]); CHKERRQ(ierr); } ierr = PetscFree(leveldegrees); CHKERRQ(ierr); ierr = PetscFree(dm); CHKERRQ(ierr); ierr = PetscFree(X); CHKERRQ(ierr); ierr = PetscFree(Xloc); CHKERRQ(ierr); ierr = PetscFree(mult); CHKERRQ(ierr); ierr = PetscFree(matO); CHKERRQ(ierr); ierr = PetscFree(matI); CHKERRQ(ierr); ierr = PetscFree(matR); CHKERRQ(ierr); ierr = PetscFree(ceeddata); CHKERRQ(ierr); ierr = PetscFree(userO); CHKERRQ(ierr); ierr = PetscFree(userI); CHKERRQ(ierr); ierr = PetscFree(userR); CHKERRQ(ierr); ierr = PetscFree(lsize); CHKERRQ(ierr); ierr = PetscFree(xlsize); CHKERRQ(ierr); ierr = PetscFree(gsize); CHKERRQ(ierr); ierr = VecDestroy(&rhs); CHKERRQ(ierr); ierr = VecDestroy(&rhsloc); CHKERRQ(ierr); ierr = KSPDestroy(&ksp); CHKERRQ(ierr); ierr = DMDestroy(&dmOrig); CHKERRQ(ierr); CeedVectorDestroy(&target); CeedQFunctionDestroy(&qf_error); CeedQFunctionDestroy(&qf_restrict); CeedQFunctionDestroy(&qf_prolong); CeedOperatorDestroy(&op_error); CeedDestroy(&ceed); return PetscFinalize(); }