166087c08SValeria Barra // Copyright (c) 2017-2018, Lawrence Livermore National Security, LLC. 266087c08SValeria Barra // Produced at the Lawrence Livermore National Laboratory. LLNL-CODE-734707. 366087c08SValeria Barra // All Rights reserved. See files LICENSE and NOTICE for details. 466087c08SValeria Barra // 566087c08SValeria Barra // This file is part of CEED, a collection of benchmarks, miniapps, software 666087c08SValeria Barra // libraries and APIs for efficient high-order finite element and spectral 766087c08SValeria Barra // element discretizations for exascale applications. For more information and 866087c08SValeria Barra // source code availability see http://github.com/ceed. 966087c08SValeria Barra // 1066087c08SValeria Barra // The CEED research is supported by the Exascale Computing Project 17-SC-20-SC, 1166087c08SValeria Barra // a collaborative effort of two U.S. Department of Energy organizations (Office 1266087c08SValeria Barra // of Science and the National Nuclear Security Administration) responsible for 1366087c08SValeria Barra // the planning and preparation of a capable exascale ecosystem, including 1466087c08SValeria Barra // software, applications, hardware, advanced system engineering and early 1566087c08SValeria Barra // testbed platforms, in support of the nation's exascale computing imperative. 1666087c08SValeria Barra 1766087c08SValeria Barra // libCEED Example 1 1866087c08SValeria Barra // 1966087c08SValeria Barra // This example illustrates a simple usage of libCEED to compute the volume of a 2066087c08SValeria Barra // 3D body using matrix-free application of a mass operator. Arbitrary mesh and 2166087c08SValeria Barra // solution orders in 1D, 2D and 3D are supported from the same code. 2266087c08SValeria Barra // 2366087c08SValeria Barra // The example has no dependencies, and is designed to be self-contained. For 2466087c08SValeria Barra // additional examples that use external discretization libraries (MFEM, PETSc, 2566087c08SValeria Barra // etc.) see the subdirectories in libceed/examples. 2666087c08SValeria Barra // 2766087c08SValeria Barra // All libCEED objects use a Ceed device object constructed based on a command 2866087c08SValeria Barra // line argument (-ceed). 2966087c08SValeria Barra // 3066087c08SValeria Barra // Build with: 3166087c08SValeria Barra // 3266087c08SValeria Barra // make ex1-volume [CEED_DIR=</path/to/libceed>] 3366087c08SValeria Barra // 3466087c08SValeria Barra // Sample runs: 3566087c08SValeria Barra // 3666087c08SValeria Barra // ./ex1-volume 3766087c08SValeria Barra // ./ex1-volume -ceed /cpu/self 3866087c08SValeria Barra // ./ex1-volume -ceed /gpu/occa 3966087c08SValeria Barra // ./ex1-volume -ceed /cpu/occa 4066087c08SValeria Barra // ./ex1-volume -ceed /omp/occa 4166087c08SValeria Barra // ./ex1-volume -ceed /ocl/occa 4266087c08SValeria Barra // ./ex1-volume -m ../../../mfem/data/fichera.mesh 4366087c08SValeria Barra // ./ex1-volume -m ../../../mfem/data/star.vtk -o 3 4466087c08SValeria Barra // ./ex1-volume -m ../../../mfem/data/inline-segment.mesh -o 8 4566087c08SValeria Barra // 4666087c08SValeria Barra // Next line is grep'd from tap.sh to set its arguments 4766087c08SValeria Barra // Test in 1D-3D 4866087c08SValeria Barra //TESTARGS -ceed {ceed_resource} -d 2 -t 4966087c08SValeria Barra //TESTARGS -ceed {ceed_resource} -d 1 -t -g 5066087c08SValeria Barra //TESTARGS -ceed {ceed_resource} -d 2 -t -g 5166087c08SValeria Barra //TESTARGS -ceed {ceed_resource} -d 3 -t -g 5266087c08SValeria Barra 5366087c08SValeria Barra /// @file 5466087c08SValeria Barra /// libCEED example using mass operator to compute volume 5566087c08SValeria Barra 5666087c08SValeria Barra #include <ceed.h> 5766087c08SValeria Barra #include <stdlib.h> 5866087c08SValeria Barra #include <math.h> 5966087c08SValeria Barra #include <string.h> 6066087c08SValeria Barra 6166087c08SValeria Barra #include "ex1-volume.h" 6266087c08SValeria Barra 6366087c08SValeria Barra // Auxiliary functions. 6466087c08SValeria Barra int GetCartesianMeshSize(int dim, int order, int prob_size, int nxyz[3]); 6566087c08SValeria Barra int BuildCartesianRestriction(Ceed ceed, int dim, int nxyz[3], int order, 6666087c08SValeria Barra int ncomp, CeedInt *size, CeedInt num_qpts, 6766087c08SValeria Barra CeedElemRestriction *restr, 6866087c08SValeria Barra CeedElemRestriction *restr_i); 6966087c08SValeria Barra int SetCartesianMeshCoords(int dim, int nxyz[3], int mesh_order, 7066087c08SValeria Barra CeedVector mesh_coords); 7166087c08SValeria Barra CeedScalar TransformMeshCoords(int dim, int mesh_size, CeedVector mesh_coords); 7266087c08SValeria Barra 7366087c08SValeria Barra 7466087c08SValeria Barra int main(int argc, const char *argv[]) { 7566087c08SValeria Barra const char *ceed_spec = "/cpu/self"; 7666087c08SValeria Barra int dim = 3; // dimension of the mesh 7766087c08SValeria Barra int ncompx = 3; // number of x components 7866087c08SValeria Barra int mesh_order = 4; // polynomial degree for the mesh 7966087c08SValeria Barra int sol_order = 4; // polynomial degree for the solution 8066087c08SValeria Barra int num_qpts = sol_order+2; // number of 1D quadrature points 8166087c08SValeria Barra int prob_size = -1; // approximate problem size 8266087c08SValeria Barra int help = 0, test = 0, gallery = 0; 8366087c08SValeria Barra 8466087c08SValeria Barra // Process command line arguments. 8566087c08SValeria Barra for (int ia = 1; ia < argc; ia++) { 8666087c08SValeria Barra int next_arg = ((ia+1) < argc), parse_error = 0; 8766087c08SValeria Barra if (!strcmp(argv[ia],"-h")) { 8866087c08SValeria Barra help = 1; 8966087c08SValeria Barra } else if (!strcmp(argv[ia],"-c") || !strcmp(argv[ia],"-ceed")) { 9066087c08SValeria Barra parse_error = next_arg ? ceed_spec = argv[++ia], 0 : 1; 9166087c08SValeria Barra } else if (!strcmp(argv[ia],"-d")) { 9266087c08SValeria Barra parse_error = next_arg ? dim = atoi(argv[++ia]), 0 : 1; 9366087c08SValeria Barra ncompx = dim; 9466087c08SValeria Barra } else if (!strcmp(argv[ia],"-m")) { 9566087c08SValeria Barra parse_error = next_arg ? mesh_order = atoi(argv[++ia]), 0 : 1; 9666087c08SValeria Barra } else if (!strcmp(argv[ia],"-o")) { 9766087c08SValeria Barra parse_error = next_arg ? sol_order = atoi(argv[++ia]), 0 : 1; 9866087c08SValeria Barra } else if (!strcmp(argv[ia],"-q")) { 9966087c08SValeria Barra parse_error = next_arg ? num_qpts = atoi(argv[++ia]), 0 : 1; 10066087c08SValeria Barra } else if (!strcmp(argv[ia],"-s")) { 10166087c08SValeria Barra parse_error = next_arg ? prob_size = atoi(argv[++ia]), 0 : 1; 10266087c08SValeria Barra } else if (!strcmp(argv[ia],"-t")) { 10366087c08SValeria Barra test = 1; 10466087c08SValeria Barra } else if (!strcmp(argv[ia],"-g")) { 10566087c08SValeria Barra gallery = 1; 10666087c08SValeria Barra } 10766087c08SValeria Barra if (parse_error) { 10866087c08SValeria Barra printf("Error parsing command line options.\n"); 10966087c08SValeria Barra return 1; 11066087c08SValeria Barra } 11166087c08SValeria Barra } 11266087c08SValeria Barra if (prob_size < 0) prob_size = test ? 8*16 : 256*1024; 11366087c08SValeria Barra 11466087c08SValeria Barra // Print the values of all options: 11566087c08SValeria Barra if (!test || help) { 11666087c08SValeria Barra printf("Selected options: [command line option] : <current value>\n"); 11766087c08SValeria Barra printf(" Ceed specification [-c] : %s\n", ceed_spec); 11866087c08SValeria Barra printf(" Mesh dimension [-d] : %d\n", dim); 11966087c08SValeria Barra printf(" Mesh order [-m] : %d\n", mesh_order); 12066087c08SValeria Barra printf(" Solution order [-o] : %d\n", sol_order); 12166087c08SValeria Barra printf(" Num. 1D quadr. pts [-q] : %d\n", num_qpts); 12266087c08SValeria Barra printf(" Approx. # unknowns [-s] : %d\n", prob_size); 12366087c08SValeria Barra printf(" QFunction source [-g] : %s\n", gallery?"gallery":"header"); 12466087c08SValeria Barra if (help) { 12566087c08SValeria Barra printf("Test/quiet mode is %s\n", (test?"ON":"OFF (use -t to enable)")); 12666087c08SValeria Barra return 0; 12766087c08SValeria Barra } 12866087c08SValeria Barra printf("\n"); 12966087c08SValeria Barra } 13066087c08SValeria Barra 13166087c08SValeria Barra // Select appropriate backend and logical device based on the <ceed-spec> 13266087c08SValeria Barra // command line argument. 13366087c08SValeria Barra Ceed ceed; 13466087c08SValeria Barra CeedInit(ceed_spec, &ceed); 13566087c08SValeria Barra 13666087c08SValeria Barra // Construct the mesh and solution bases. 13766087c08SValeria Barra CeedBasis mesh_basis, sol_basis; 13866087c08SValeria Barra CeedBasisCreateTensorH1Lagrange(ceed, dim, ncompx, mesh_order+1, num_qpts, 13966087c08SValeria Barra CEED_GAUSS, &mesh_basis); 14066087c08SValeria Barra CeedBasisCreateTensorH1Lagrange(ceed, dim, 1, sol_order+1, num_qpts, 14166087c08SValeria Barra CEED_GAUSS, &sol_basis); 14266087c08SValeria Barra 14366087c08SValeria Barra // Determine the mesh size based on the given approximate problem size. 14466087c08SValeria Barra int nxyz[dim]; 14566087c08SValeria Barra GetCartesianMeshSize(dim, sol_order, prob_size, nxyz); 14666087c08SValeria Barra 14766087c08SValeria Barra if (!test) { 14866087c08SValeria Barra printf("Mesh size: nx = %d", nxyz[0]); 14966087c08SValeria Barra if (dim > 1) { printf(", ny = %d", nxyz[1]); } 15066087c08SValeria Barra if (dim > 2) { printf(", nz = %d", nxyz[2]); } 15166087c08SValeria Barra printf("\n"); 15266087c08SValeria Barra } 15366087c08SValeria Barra 15466087c08SValeria Barra // Build CeedElemRestriction objects describing the mesh and solution discrete 15566087c08SValeria Barra // representations. 15666087c08SValeria Barra CeedInt mesh_size, sol_size; 15766087c08SValeria Barra CeedElemRestriction mesh_restr, sol_restr, mesh_restr_i, sol_restr_i; 15866087c08SValeria Barra BuildCartesianRestriction(ceed, dim, nxyz, mesh_order, ncompx, &mesh_size, 15966087c08SValeria Barra num_qpts, &mesh_restr, &mesh_restr_i); 16066087c08SValeria Barra BuildCartesianRestriction(ceed, dim, nxyz, sol_order, 1, &sol_size, 16166087c08SValeria Barra num_qpts, &sol_restr, &sol_restr_i); 16266087c08SValeria Barra if (!test) { 16366087c08SValeria Barra printf("Number of mesh nodes : %d\n", mesh_size/dim); 16466087c08SValeria Barra printf("Number of solution nodes : %d\n", sol_size); 16566087c08SValeria Barra } 16666087c08SValeria Barra 16766087c08SValeria Barra // Create a CeedVector with the mesh coordinates. 16866087c08SValeria Barra CeedVector mesh_coords; 16966087c08SValeria Barra CeedVectorCreate(ceed, mesh_size, &mesh_coords); 17066087c08SValeria Barra SetCartesianMeshCoords(dim, nxyz, mesh_order, mesh_coords); 17166087c08SValeria Barra 17266087c08SValeria Barra // Apply a transformation to the mesh. 17366087c08SValeria Barra CeedScalar exact_vol = TransformMeshCoords(dim, mesh_size, mesh_coords); 17466087c08SValeria Barra 17566087c08SValeria Barra // Context data to be passed to the 'f_build_mass' Q-function. 17666087c08SValeria Barra struct BuildContext build_ctx; 17766087c08SValeria Barra build_ctx.dim = build_ctx.space_dim = dim; 17866087c08SValeria Barra 17966087c08SValeria Barra // Create the Q-function that builds the mass operator (i.e. computes its 18066087c08SValeria Barra // quadrature data) and set its context data. 18166087c08SValeria Barra CeedQFunction build_qfunc; 18266087c08SValeria Barra switch (gallery) { 18366087c08SValeria Barra case 0: 18466087c08SValeria Barra // This creates the QFunction directly. 18566087c08SValeria Barra CeedQFunctionCreateInterior(ceed, 1, f_build_mass, 18666087c08SValeria Barra f_build_mass_loc, &build_qfunc); 18766087c08SValeria Barra CeedQFunctionAddInput(build_qfunc, "dx", ncompx*dim, CEED_EVAL_GRAD); 18866087c08SValeria Barra CeedQFunctionAddInput(build_qfunc, "weights", 1, CEED_EVAL_WEIGHT); 18966087c08SValeria Barra CeedQFunctionAddOutput(build_qfunc, "qdata", 1, CEED_EVAL_NONE); 19066087c08SValeria Barra CeedQFunctionSetContext(build_qfunc, &build_ctx, sizeof(build_ctx)); 19166087c08SValeria Barra break; 19266087c08SValeria Barra case 1: { 19366087c08SValeria Barra // This creates the QFunction via the gallery. 19466087c08SValeria Barra char name[13] = ""; 19566087c08SValeria Barra snprintf(name, sizeof name, "Mass%dDBuild", dim); 19666087c08SValeria Barra CeedQFunctionCreateInteriorByName(ceed, name, &build_qfunc); 19766087c08SValeria Barra break; 19866087c08SValeria Barra } 19966087c08SValeria Barra } 20066087c08SValeria Barra 20166087c08SValeria Barra // Create the operator that builds the quadrature data for the mass operator. 20266087c08SValeria Barra CeedOperator build_oper; 20366087c08SValeria Barra CeedOperatorCreate(ceed, build_qfunc, CEED_QFUNCTION_NONE, 20466087c08SValeria Barra CEED_QFUNCTION_NONE, &build_oper); 205a8d32208Sjeremylt CeedOperatorSetField(build_oper, "dx", mesh_restr, mesh_basis, 206a8d32208Sjeremylt CEED_VECTOR_ACTIVE); 207a8d32208Sjeremylt CeedOperatorSetField(build_oper, "weights", mesh_restr_i, mesh_basis, 208a8d32208Sjeremylt CEED_VECTOR_NONE); 209a8d32208Sjeremylt CeedOperatorSetField(build_oper, "qdata", sol_restr_i, CEED_BASIS_COLLOCATED, 210a8d32208Sjeremylt CEED_VECTOR_ACTIVE); 21166087c08SValeria Barra 21266087c08SValeria Barra // Compute the quadrature data for the mass operator. 21366087c08SValeria Barra CeedVector qdata; 21466087c08SValeria Barra CeedInt elem_qpts = CeedIntPow(num_qpts, dim); 21566087c08SValeria Barra CeedInt num_elem = 1; 21666087c08SValeria Barra for (int d = 0; d < dim; d++) 21766087c08SValeria Barra num_elem *= nxyz[d]; 21866087c08SValeria Barra CeedVectorCreate(ceed, num_elem*elem_qpts, &qdata); 21966087c08SValeria Barra if (!test) { 22066087c08SValeria Barra printf("Computing the quadrature data for the mass operator ..."); 22166087c08SValeria Barra fflush(stdout); 22266087c08SValeria Barra } 22366087c08SValeria Barra CeedOperatorApply(build_oper, mesh_coords, qdata, 22466087c08SValeria Barra CEED_REQUEST_IMMEDIATE); 22566087c08SValeria Barra if (!test) { 22666087c08SValeria Barra printf(" done.\n"); 22766087c08SValeria Barra } 22866087c08SValeria Barra 22966087c08SValeria Barra // Create the Q-function that defines the action of the mass operator. 23066087c08SValeria Barra CeedQFunction apply_qfunc; 23166087c08SValeria Barra switch (gallery) { 23266087c08SValeria Barra case 0: 23366087c08SValeria Barra // This creates the QFunction directly. 23466087c08SValeria Barra CeedQFunctionCreateInterior(ceed, 1, f_apply_mass, 23566087c08SValeria Barra f_apply_mass_loc, &apply_qfunc); 23666087c08SValeria Barra CeedQFunctionAddInput(apply_qfunc, "u", 1, CEED_EVAL_INTERP); 23766087c08SValeria Barra CeedQFunctionAddInput(apply_qfunc, "qdata", 1, CEED_EVAL_NONE); 23866087c08SValeria Barra CeedQFunctionAddOutput(apply_qfunc, "v", 1, CEED_EVAL_INTERP); 23966087c08SValeria Barra break; 24066087c08SValeria Barra case 1: 24166087c08SValeria Barra // This creates the QFunction via the gallery. 24266087c08SValeria Barra CeedQFunctionCreateInteriorByName(ceed, "MassApply", &apply_qfunc); 24366087c08SValeria Barra break; 24466087c08SValeria Barra } 24566087c08SValeria Barra 24666087c08SValeria Barra // Create the mass operator. 24766087c08SValeria Barra CeedOperator oper; 24866087c08SValeria Barra CeedOperatorCreate(ceed, apply_qfunc, CEED_QFUNCTION_NONE, 24966087c08SValeria Barra CEED_QFUNCTION_NONE, &oper); 250a8d32208Sjeremylt CeedOperatorSetField(oper, "u", sol_restr, sol_basis, CEED_VECTOR_ACTIVE); 251a8d32208Sjeremylt CeedOperatorSetField(oper, "qdata", sol_restr_i, CEED_BASIS_COLLOCATED, 252a8d32208Sjeremylt qdata); 253a8d32208Sjeremylt CeedOperatorSetField(oper, "v", sol_restr, sol_basis, CEED_VECTOR_ACTIVE); 25466087c08SValeria Barra 25566087c08SValeria Barra // Compute the mesh volume using the mass operator: vol = 1^T \cdot M \cdot 1 25666087c08SValeria Barra if (!test) { 25766087c08SValeria Barra printf("Computing the mesh volume using the formula: vol = 1^T.M.1 ..."); 25866087c08SValeria Barra fflush(stdout); 25966087c08SValeria Barra } 26066087c08SValeria Barra 26166087c08SValeria Barra // Create auxiliary solution-size vectors. 26266087c08SValeria Barra CeedVector u, v; 26366087c08SValeria Barra CeedVectorCreate(ceed, sol_size, &u); 26466087c08SValeria Barra CeedVectorCreate(ceed, sol_size, &v); 26566087c08SValeria Barra 26666087c08SValeria Barra // Initialize 'u' and 'v' with ones. 26766087c08SValeria Barra CeedVectorSetValue(u, 1.0); 26866087c08SValeria Barra 26966087c08SValeria Barra // Apply the mass operator: 'u' -> 'v'. 27066087c08SValeria Barra CeedOperatorApply(oper, u, v, CEED_REQUEST_IMMEDIATE); 27166087c08SValeria Barra 27266087c08SValeria Barra // Compute and print the sum of the entries of 'v' giving the mesh volume. 27366087c08SValeria Barra const CeedScalar *v_host; 27466087c08SValeria Barra CeedVectorGetArrayRead(v, CEED_MEM_HOST, &v_host); 27566087c08SValeria Barra CeedScalar vol = 0.; 27666087c08SValeria Barra for (CeedInt i = 0; i < sol_size; i++) { 27766087c08SValeria Barra vol += v_host[i]; 27866087c08SValeria Barra } 27966087c08SValeria Barra CeedVectorRestoreArrayRead(v, &v_host); 28066087c08SValeria Barra if (!test) { 28166087c08SValeria Barra printf(" done.\n"); 28266087c08SValeria Barra printf("Exact mesh volume : % .14g\n", exact_vol); 28366087c08SValeria Barra printf("Computed mesh volume : % .14g\n", vol); 28466087c08SValeria Barra printf("Volume error : % .14g\n", vol-exact_vol); 28566087c08SValeria Barra } else { 28666087c08SValeria Barra CeedScalar tol = (dim==1? 1E-14 : dim==2? 1E-7 : 1E-5); 28766087c08SValeria Barra if (fabs(vol-exact_vol)>tol) 28866087c08SValeria Barra printf("Volume error : % .1e\n", vol-exact_vol); 28966087c08SValeria Barra } 29066087c08SValeria Barra 29166087c08SValeria Barra // Free dynamically allocated memory. 29266087c08SValeria Barra CeedVectorDestroy(&u); 29366087c08SValeria Barra CeedVectorDestroy(&v); 29466087c08SValeria Barra CeedVectorDestroy(&qdata); 29566087c08SValeria Barra CeedVectorDestroy(&mesh_coords); 29666087c08SValeria Barra CeedOperatorDestroy(&oper); 29766087c08SValeria Barra CeedQFunctionDestroy(&apply_qfunc); 29866087c08SValeria Barra CeedOperatorDestroy(&build_oper); 29966087c08SValeria Barra CeedQFunctionDestroy(&build_qfunc); 30066087c08SValeria Barra CeedElemRestrictionDestroy(&sol_restr); 30166087c08SValeria Barra CeedElemRestrictionDestroy(&mesh_restr); 30266087c08SValeria Barra CeedElemRestrictionDestroy(&sol_restr_i); 30366087c08SValeria Barra CeedElemRestrictionDestroy(&mesh_restr_i); 30466087c08SValeria Barra CeedBasisDestroy(&sol_basis); 30566087c08SValeria Barra CeedBasisDestroy(&mesh_basis); 30666087c08SValeria Barra CeedDestroy(&ceed); 30766087c08SValeria Barra return 0; 30866087c08SValeria Barra } 30966087c08SValeria Barra 31066087c08SValeria Barra 31166087c08SValeria Barra int GetCartesianMeshSize(int dim, int order, int prob_size, int nxyz[dim]) { 31266087c08SValeria Barra // Use the approximate formula: 31366087c08SValeria Barra // prob_size ~ num_elem * order^dim 31466087c08SValeria Barra CeedInt num_elem = prob_size / CeedIntPow(order, dim); 31566087c08SValeria Barra CeedInt s = 0; // find s: num_elem/2 < 2^s <= num_elem 31666087c08SValeria Barra while (num_elem > 1) { 31766087c08SValeria Barra num_elem /= 2; 31866087c08SValeria Barra s++; 31966087c08SValeria Barra } 32066087c08SValeria Barra CeedInt r = s%dim; 32166087c08SValeria Barra for (int d = 0; d < dim; d++) { 32266087c08SValeria Barra int sd = s/dim; 32366087c08SValeria Barra if (r > 0) { sd++; r--; } 32466087c08SValeria Barra nxyz[d] = 1 << sd; 32566087c08SValeria Barra } 32666087c08SValeria Barra return 0; 32766087c08SValeria Barra } 32866087c08SValeria Barra 32966087c08SValeria Barra int BuildCartesianRestriction(Ceed ceed, int dim, int nxyz[dim], int order, 33066087c08SValeria Barra int ncomp, CeedInt *size, CeedInt num_qpts, 33166087c08SValeria Barra CeedElemRestriction *restr, 33266087c08SValeria Barra CeedElemRestriction *restr_i) { 333a8d32208Sjeremylt CeedTransposeMode lmode = CEED_NOTRANSPOSE; 33466087c08SValeria Barra CeedInt p = order, pp1 = p+1; 33566087c08SValeria Barra CeedInt nnodes = CeedIntPow(pp1, dim); // number of scal. nodes per element 33666087c08SValeria Barra CeedInt elem_qpts = CeedIntPow(num_qpts, dim); // number of qpts per element 33766087c08SValeria Barra CeedInt nd[3], num_elem = 1, scalar_size = 1; 33866087c08SValeria Barra for (int d = 0; d < dim; d++) { 33966087c08SValeria Barra num_elem *= nxyz[d]; 34066087c08SValeria Barra nd[d] = nxyz[d]*p + 1; 34166087c08SValeria Barra scalar_size *= nd[d]; 34266087c08SValeria Barra } 34366087c08SValeria Barra *size = scalar_size*ncomp; 34466087c08SValeria Barra // elem: 0 1 n-1 34566087c08SValeria Barra // |---*-...-*---|---*-...-*---|- ... -|--...--| 34666087c08SValeria Barra // nnodes: 0 1 p-1 p p+1 2*p n*p 34766087c08SValeria Barra CeedInt *el_nodes = malloc(sizeof(CeedInt)*num_elem*nnodes); 34866087c08SValeria Barra for (CeedInt e = 0; e < num_elem; e++) { 349*2d4f38ccSjeremylt CeedInt exyz[3] = {1, 1, 1}, re = e; 35066087c08SValeria Barra for (int d = 0; d < dim; d++) { exyz[d] = re%nxyz[d]; re /= nxyz[d]; } 35166087c08SValeria Barra CeedInt *loc_el_nodes = el_nodes + e*nnodes; 35266087c08SValeria Barra for (int lnodes = 0; lnodes < nnodes; lnodes++) { 35366087c08SValeria Barra CeedInt gnodes = 0, gnodes_stride = 1, rnodes = lnodes; 35466087c08SValeria Barra for (int d = 0; d < dim; d++) { 35566087c08SValeria Barra gnodes += (exyz[d]*p + rnodes%pp1) * gnodes_stride; 35666087c08SValeria Barra gnodes_stride *= nd[d]; 35766087c08SValeria Barra rnodes /= pp1; 35866087c08SValeria Barra } 35966087c08SValeria Barra loc_el_nodes[lnodes] = gnodes; 36066087c08SValeria Barra } 36166087c08SValeria Barra } 362a8d32208Sjeremylt CeedElemRestrictionCreate(ceed, lmode, num_elem, nnodes, scalar_size, 363a8d32208Sjeremylt ncomp, CEED_MEM_HOST, CEED_COPY_VALUES, el_nodes, 364a8d32208Sjeremylt restr); 365a8d32208Sjeremylt CeedElemRestrictionCreateIdentity(ceed, lmode, num_elem, elem_qpts, 366a8d32208Sjeremylt elem_qpts*num_elem, ncomp, restr_i); 36766087c08SValeria Barra free(el_nodes); 36866087c08SValeria Barra return 0; 36966087c08SValeria Barra } 37066087c08SValeria Barra 37166087c08SValeria Barra int SetCartesianMeshCoords(int dim, int nxyz[dim], int mesh_order, 37266087c08SValeria Barra CeedVector mesh_coords) { 37366087c08SValeria Barra CeedInt p = mesh_order; 37466087c08SValeria Barra CeedInt nd[3], num_elem = 1, scalar_size = 1; 37566087c08SValeria Barra for (int d = 0; d < dim; d++) { 37666087c08SValeria Barra num_elem *= nxyz[d]; 37766087c08SValeria Barra nd[d] = nxyz[d]*p + 1; 37866087c08SValeria Barra scalar_size *= nd[d]; 37966087c08SValeria Barra } 38066087c08SValeria Barra CeedScalar *coords; 38166087c08SValeria Barra CeedVectorGetArray(mesh_coords, CEED_MEM_HOST, &coords); 38266087c08SValeria Barra CeedScalar *nodes = malloc(sizeof(CeedScalar)*(p+1)); 38366087c08SValeria Barra // The H1 basis uses Lobatto quadrature points as nodes. 38466087c08SValeria Barra CeedLobattoQuadrature(p+1, nodes, NULL); // nodes are in [-1,1] 38566087c08SValeria Barra for (CeedInt i = 0; i <= p; i++) { nodes[i] = 0.5+0.5*nodes[i]; } 38666087c08SValeria Barra for (CeedInt gsnodes = 0; gsnodes < scalar_size; gsnodes++) { 38766087c08SValeria Barra CeedInt rnodes = gsnodes; 38866087c08SValeria Barra for (int d = 0; d < dim; d++) { 38966087c08SValeria Barra CeedInt d1d = rnodes%nd[d]; 39066087c08SValeria Barra coords[gsnodes+scalar_size*d] = ((d1d/p)+nodes[d1d%p]) / nxyz[d]; 39166087c08SValeria Barra rnodes /= nd[d]; 39266087c08SValeria Barra } 39366087c08SValeria Barra } 39466087c08SValeria Barra free(nodes); 39566087c08SValeria Barra CeedVectorRestoreArray(mesh_coords, &coords); 39666087c08SValeria Barra return 0; 39766087c08SValeria Barra } 39866087c08SValeria Barra 39966087c08SValeria Barra #ifndef M_PI 40066087c08SValeria Barra #define M_PI 3.14159265358979323846 40166087c08SValeria Barra #define M_PI_2 1.57079632679489661923 40266087c08SValeria Barra #endif 40366087c08SValeria Barra 40466087c08SValeria Barra CeedScalar TransformMeshCoords(int dim, int mesh_size, CeedVector mesh_coords) { 40566087c08SValeria Barra CeedScalar exact_volume; 40666087c08SValeria Barra CeedScalar *coords; 40766087c08SValeria Barra CeedVectorGetArray(mesh_coords, CEED_MEM_HOST, &coords); 40866087c08SValeria Barra if (dim == 1) { 40966087c08SValeria Barra for (CeedInt i = 0; i < mesh_size; i++) { 41066087c08SValeria Barra // map [0,1] to [0,1] varying the mesh density 41166087c08SValeria Barra coords[i] = 0.5+1./sqrt(3.)*sin((2./3.)*M_PI*(coords[i]-0.5)); 41266087c08SValeria Barra } 41366087c08SValeria Barra exact_volume = 1.; 41466087c08SValeria Barra } else { 41566087c08SValeria Barra CeedInt num_nodes = mesh_size/dim; 41666087c08SValeria Barra for (CeedInt i = 0; i < num_nodes; i++) { 41766087c08SValeria Barra // map (x,y) from [0,1]x[0,1] to the quarter annulus with polar 41866087c08SValeria Barra // coordinates, (r,phi) in [1,2]x[0,pi/2] with area = 3/4*pi 41966087c08SValeria Barra CeedScalar u = coords[i], v = coords[i+num_nodes]; 42066087c08SValeria Barra u = 1.+u; 42166087c08SValeria Barra v = M_PI_2*v; 42266087c08SValeria Barra coords[i] = u*cos(v); 42366087c08SValeria Barra coords[i+num_nodes] = u*sin(v); 42466087c08SValeria Barra } 42566087c08SValeria Barra exact_volume = 3./4.*M_PI; 42666087c08SValeria Barra } 42766087c08SValeria Barra CeedVectorRestoreArray(mesh_coords, &coords); 42866087c08SValeria Barra return exact_volume; 42966087c08SValeria Barra } 430