1*2027fb9dSSirAlienTheGreat // Copyright (c) 2017-2025, Lawrence Livermore National Security, LLC and other CEED contributors. 2*2027fb9dSSirAlienTheGreat // All Rights Reserved. See the top-level LICENSE and NOTICE files for details. 3*2027fb9dSSirAlienTheGreat // 4*2027fb9dSSirAlienTheGreat // SPDX-License-Identifier: BSD-2-Clause 5*2027fb9dSSirAlienTheGreat // 6*2027fb9dSSirAlienTheGreat // This file is part of CEED: http://github.com/ceed 7*2027fb9dSSirAlienTheGreat 8*2027fb9dSSirAlienTheGreat // libCEED Example 1 9*2027fb9dSSirAlienTheGreat // 10*2027fb9dSSirAlienTheGreat // This example illustrates a simple usage of libCEED to compute the volume of a 3D body using matrix-free application of a mass operator. 11*2027fb9dSSirAlienTheGreat // Arbitrary mesh and solution degrees in 1D, 2D and 3D are supported from the same code. 12*2027fb9dSSirAlienTheGreat // 13*2027fb9dSSirAlienTheGreat // The example has no dependencies, and is designed to be self-contained. 14*2027fb9dSSirAlienTheGreat // For additional examples that use external discretization libraries (MFEM, PETSc, etc.) see the subdirectories in libceed/examples. 15*2027fb9dSSirAlienTheGreat // 16*2027fb9dSSirAlienTheGreat // All libCEED objects use a Ceed device object constructed based on a command line argument (-ceed). 17*2027fb9dSSirAlienTheGreat // 18*2027fb9dSSirAlienTheGreat // Build with: 19*2027fb9dSSirAlienTheGreat // 20*2027fb9dSSirAlienTheGreat // make ex1-volume-rust [CEED_DIR=</path/to/libceed>] 21*2027fb9dSSirAlienTheGreat // 22*2027fb9dSSirAlienTheGreat // Sample runs: 23*2027fb9dSSirAlienTheGreat // 24*2027fb9dSSirAlienTheGreat // ./ex1-volume 25*2027fb9dSSirAlienTheGreat // ./ex1-volume -ceed /cpu/self 26*2027fb9dSSirAlienTheGreat // ./ex1-volume -ceed /gpu/cuda 27*2027fb9dSSirAlienTheGreat // 28*2027fb9dSSirAlienTheGreat // Test in 1D-3D 29*2027fb9dSSirAlienTheGreat //TESTARGS(name="1D User QFunction") -ceed {ceed_resource} -d 1 -t 30*2027fb9dSSirAlienTheGreat //TESTARGS(name="2D User QFunction") -ceed {ceed_resource} -d 2 -t 31*2027fb9dSSirAlienTheGreat //TESTARGS(name="3D User QFunction") -ceed {ceed_resource} -d 3 -t 32*2027fb9dSSirAlienTheGreat //TESTARGS(name="1D Gallery QFunction") -ceed {ceed_resource} -d 1 -t -g 33*2027fb9dSSirAlienTheGreat //TESTARGS(name="2D Gallery QFunction") -ceed {ceed_resource} -d 2 -t -g 34*2027fb9dSSirAlienTheGreat //TESTARGS(name="3D Gallery QFunction") -ceed {ceed_resource} -d 3 -t -g 35*2027fb9dSSirAlienTheGreat 36*2027fb9dSSirAlienTheGreat /// @file 37*2027fb9dSSirAlienTheGreat /// libCEED example using mass operator to compute volume 38*2027fb9dSSirAlienTheGreat 39*2027fb9dSSirAlienTheGreat #include "ex1-volume.h" 40*2027fb9dSSirAlienTheGreat 41*2027fb9dSSirAlienTheGreat #include <ceed.h> 42*2027fb9dSSirAlienTheGreat #include <math.h> 43*2027fb9dSSirAlienTheGreat #include <stdint.h> 44*2027fb9dSSirAlienTheGreat #include <stdio.h> 45*2027fb9dSSirAlienTheGreat #include <stdlib.h> 46*2027fb9dSSirAlienTheGreat #include <string.h> 47*2027fb9dSSirAlienTheGreat 48*2027fb9dSSirAlienTheGreat // Auxiliary functions 49*2027fb9dSSirAlienTheGreat int GetCartesianMeshSize(CeedInt dim, CeedInt degree, CeedInt prob_size, CeedInt num_xyz[dim]); 50*2027fb9dSSirAlienTheGreat int BuildCartesianRestriction(Ceed ceed, CeedInt dim, CeedInt num_xyz[dim], CeedInt degree, CeedInt num_comp, CeedInt *size, CeedInt num_qpts, 51*2027fb9dSSirAlienTheGreat CeedElemRestriction *restriction, CeedElemRestriction *q_data_restriction); 52*2027fb9dSSirAlienTheGreat int SetCartesianMeshCoords(CeedInt dim, CeedInt num_xyz[dim], CeedInt mesh_degree, CeedVector mesh_coords); 53*2027fb9dSSirAlienTheGreat CeedScalar TransformMeshCoords(CeedInt dim, CeedInt mesh_size, CeedVector mesh_coords); 54*2027fb9dSSirAlienTheGreat 55*2027fb9dSSirAlienTheGreat // Main example 56*2027fb9dSSirAlienTheGreat int main(int argc, const char *argv[]) { 57*2027fb9dSSirAlienTheGreat const char *ceed_spec = "/cpu/self"; 58*2027fb9dSSirAlienTheGreat CeedInt dim = 3; // dimension of the mesh 59*2027fb9dSSirAlienTheGreat CeedInt num_comp_x = 3; // number of x components 60*2027fb9dSSirAlienTheGreat CeedInt mesh_degree = 4; // polynomial degree for the mesh 61*2027fb9dSSirAlienTheGreat CeedInt sol_degree = 4; // polynomial degree for the solution 62*2027fb9dSSirAlienTheGreat CeedInt num_qpts = sol_degree + 2; // number of 1D quadrature points 63*2027fb9dSSirAlienTheGreat CeedInt prob_size = -1; // approximate problem size 64*2027fb9dSSirAlienTheGreat CeedInt help = 0, test = 0, gallery = 0, benchmark = 0; 65*2027fb9dSSirAlienTheGreat 66*2027fb9dSSirAlienTheGreat // Process command line arguments. 67*2027fb9dSSirAlienTheGreat for (int ia = 1; ia < argc; ia++) { 68*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 69*2027fb9dSSirAlienTheGreat int next_arg = ((ia + 1) < argc), parse_error = 0; 70*2027fb9dSSirAlienTheGreat if (!strcmp(argv[ia], "-h")) { 71*2027fb9dSSirAlienTheGreat help = 1; 72*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-c") || !strcmp(argv[ia], "-ceed")) { 73*2027fb9dSSirAlienTheGreat parse_error = next_arg ? ceed_spec = argv[++ia], 0 : 1; 74*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-d")) { 75*2027fb9dSSirAlienTheGreat parse_error = next_arg ? dim = atoi(argv[++ia]), 0 : 1; 76*2027fb9dSSirAlienTheGreat num_comp_x = dim; 77*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-m")) { 78*2027fb9dSSirAlienTheGreat parse_error = next_arg ? mesh_degree = atoi(argv[++ia]), 0 : 1; 79*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-p")) { 80*2027fb9dSSirAlienTheGreat parse_error = next_arg ? sol_degree = atoi(argv[++ia]), 0 : 1; 81*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-q")) { 82*2027fb9dSSirAlienTheGreat parse_error = next_arg ? num_qpts = atoi(argv[++ia]), 0 : 1; 83*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-s")) { 84*2027fb9dSSirAlienTheGreat parse_error = next_arg ? prob_size = atoi(argv[++ia]), 0 : 1; 85*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-b")) { 86*2027fb9dSSirAlienTheGreat parse_error = next_arg ? benchmark = atoi(argv[++ia]), 0 : 1; 87*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-t")) { 88*2027fb9dSSirAlienTheGreat test = 1; 89*2027fb9dSSirAlienTheGreat } else if (!strcmp(argv[ia], "-g")) { 90*2027fb9dSSirAlienTheGreat gallery = 1; 91*2027fb9dSSirAlienTheGreat } 92*2027fb9dSSirAlienTheGreat if (parse_error) { 93*2027fb9dSSirAlienTheGreat printf("Error parsing command line options.\n"); 94*2027fb9dSSirAlienTheGreat return 1; 95*2027fb9dSSirAlienTheGreat } 96*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 97*2027fb9dSSirAlienTheGreat } 98*2027fb9dSSirAlienTheGreat if (prob_size < 0) prob_size = test ? 8 * 16 : 256 * 1024; 99*2027fb9dSSirAlienTheGreat 100*2027fb9dSSirAlienTheGreat // Print the values of all options: 101*2027fb9dSSirAlienTheGreat if (!test || help) { 102*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 103*2027fb9dSSirAlienTheGreat printf("Selected options: [command line option] : <current value>\n"); 104*2027fb9dSSirAlienTheGreat printf(" Ceed specification [-c] : %s\n", ceed_spec); 105*2027fb9dSSirAlienTheGreat printf(" Mesh dimension [-d] : %" CeedInt_FMT "\n", dim); 106*2027fb9dSSirAlienTheGreat printf(" Mesh degree [-m] : %" CeedInt_FMT "\n", mesh_degree); 107*2027fb9dSSirAlienTheGreat printf(" Solution degree [-p] : %" CeedInt_FMT "\n", sol_degree); 108*2027fb9dSSirAlienTheGreat printf(" Num. 1D quadrature pts [-q] : %" CeedInt_FMT "\n", num_qpts); 109*2027fb9dSSirAlienTheGreat printf(" Approx. # unknowns [-s] : %" CeedInt_FMT "\n", prob_size); 110*2027fb9dSSirAlienTheGreat printf(" QFunction source [-g] : %s\n", gallery ? "gallery" : "header"); 111*2027fb9dSSirAlienTheGreat if (help) { 112*2027fb9dSSirAlienTheGreat printf("Test/quiet mode is %s\n", (test ? "ON" : "OFF (use -t to enable)")); 113*2027fb9dSSirAlienTheGreat return 0; 114*2027fb9dSSirAlienTheGreat } 115*2027fb9dSSirAlienTheGreat printf("\n"); 116*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 117*2027fb9dSSirAlienTheGreat } 118*2027fb9dSSirAlienTheGreat 119*2027fb9dSSirAlienTheGreat // Select appropriate backend and logical device based on the (-ceed) command line argument. 120*2027fb9dSSirAlienTheGreat Ceed ceed; 121*2027fb9dSSirAlienTheGreat 122*2027fb9dSSirAlienTheGreat CeedInit(ceed_spec, &ceed); 123*2027fb9dSSirAlienTheGreat 124*2027fb9dSSirAlienTheGreat // Add the path to the Rust crate to the ceed object. 125*2027fb9dSSirAlienTheGreat { 126*2027fb9dSSirAlienTheGreat char root[2048] = __FILE__; 127*2027fb9dSSirAlienTheGreat char *last_slash = strrchr(root, '/'); 128*2027fb9dSSirAlienTheGreat 129*2027fb9dSSirAlienTheGreat strncpy(last_slash + 1, "ex1-volume-rs", 14); 130*2027fb9dSSirAlienTheGreat CeedAddRustSourceRoot(ceed, root); 131*2027fb9dSSirAlienTheGreat } 132*2027fb9dSSirAlienTheGreat 133*2027fb9dSSirAlienTheGreat // Construct the mesh and solution bases. 134*2027fb9dSSirAlienTheGreat CeedBasis mesh_basis, sol_basis; 135*2027fb9dSSirAlienTheGreat 136*2027fb9dSSirAlienTheGreat CeedBasisCreateTensorH1Lagrange(ceed, dim, num_comp_x, mesh_degree + 1, num_qpts, CEED_GAUSS, &mesh_basis); 137*2027fb9dSSirAlienTheGreat CeedBasisCreateTensorH1Lagrange(ceed, dim, 1, sol_degree + 1, num_qpts, CEED_GAUSS, &sol_basis); 138*2027fb9dSSirAlienTheGreat 139*2027fb9dSSirAlienTheGreat // Determine the mesh size based on the given approximate problem size. 140*2027fb9dSSirAlienTheGreat CeedInt num_xyz[dim]; 141*2027fb9dSSirAlienTheGreat 142*2027fb9dSSirAlienTheGreat GetCartesianMeshSize(dim, sol_degree, prob_size, num_xyz); 143*2027fb9dSSirAlienTheGreat if (!test) { 144*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 145*2027fb9dSSirAlienTheGreat printf("Mesh size: nx = %" CeedInt_FMT, num_xyz[0]); 146*2027fb9dSSirAlienTheGreat if (dim > 1) printf(", ny = %" CeedInt_FMT, num_xyz[1]); 147*2027fb9dSSirAlienTheGreat if (dim > 2) printf(", nz = %" CeedInt_FMT, num_xyz[2]); 148*2027fb9dSSirAlienTheGreat printf("\n"); 149*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 150*2027fb9dSSirAlienTheGreat } 151*2027fb9dSSirAlienTheGreat 152*2027fb9dSSirAlienTheGreat // Build CeedElemRestriction objects describing the mesh and solution discrete representations. 153*2027fb9dSSirAlienTheGreat CeedInt mesh_size, sol_size; 154*2027fb9dSSirAlienTheGreat CeedElemRestriction mesh_restriction, sol_restriction, q_data_restriction; 155*2027fb9dSSirAlienTheGreat 156*2027fb9dSSirAlienTheGreat BuildCartesianRestriction(ceed, dim, num_xyz, mesh_degree, num_comp_x, &mesh_size, num_qpts, &mesh_restriction, NULL); 157*2027fb9dSSirAlienTheGreat BuildCartesianRestriction(ceed, dim, num_xyz, sol_degree, 1, &sol_size, num_qpts, &sol_restriction, &q_data_restriction); 158*2027fb9dSSirAlienTheGreat if (!test) { 159*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 160*2027fb9dSSirAlienTheGreat printf("Number of mesh nodes : %" CeedInt_FMT "\n", mesh_size / dim); 161*2027fb9dSSirAlienTheGreat printf("Number of solution nodes : %" CeedInt_FMT "\n", sol_size); 162*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 163*2027fb9dSSirAlienTheGreat } 164*2027fb9dSSirAlienTheGreat 165*2027fb9dSSirAlienTheGreat // Create a CeedVector with the mesh coordinates. 166*2027fb9dSSirAlienTheGreat CeedVector mesh_coords; 167*2027fb9dSSirAlienTheGreat 168*2027fb9dSSirAlienTheGreat CeedVectorCreate(ceed, mesh_size, &mesh_coords); 169*2027fb9dSSirAlienTheGreat SetCartesianMeshCoords(dim, num_xyz, mesh_degree, mesh_coords); 170*2027fb9dSSirAlienTheGreat 171*2027fb9dSSirAlienTheGreat // Apply a transformation to the mesh. 172*2027fb9dSSirAlienTheGreat CeedScalar exact_volume = TransformMeshCoords(dim, mesh_size, mesh_coords); 173*2027fb9dSSirAlienTheGreat 174*2027fb9dSSirAlienTheGreat // Context data to be passed to the 'build_mass' QFunction. 175*2027fb9dSSirAlienTheGreat CeedQFunctionContext build_ctx; 176*2027fb9dSSirAlienTheGreat struct BuildContext build_ctx_data; 177*2027fb9dSSirAlienTheGreat 178*2027fb9dSSirAlienTheGreat build_ctx_data.dim = build_ctx_data.space_dim = dim; 179*2027fb9dSSirAlienTheGreat CeedQFunctionContextCreate(ceed, &build_ctx); 180*2027fb9dSSirAlienTheGreat CeedQFunctionContextSetData(build_ctx, CEED_MEM_HOST, CEED_USE_POINTER, sizeof(build_ctx_data), &build_ctx_data); 181*2027fb9dSSirAlienTheGreat 182*2027fb9dSSirAlienTheGreat // Create the QFunction that builds the mass operator (i.e. computes its quadrature data) and set its context data. 183*2027fb9dSSirAlienTheGreat CeedQFunction qf_build; 184*2027fb9dSSirAlienTheGreat 185*2027fb9dSSirAlienTheGreat if (gallery) { 186*2027fb9dSSirAlienTheGreat // This creates the QFunction via the gallery. 187*2027fb9dSSirAlienTheGreat char name[13] = ""; 188*2027fb9dSSirAlienTheGreat snprintf(name, sizeof name, "Mass%" CeedInt_FMT "DBuild", dim); 189*2027fb9dSSirAlienTheGreat CeedQFunctionCreateInteriorByName(ceed, name, &qf_build); 190*2027fb9dSSirAlienTheGreat } else { 191*2027fb9dSSirAlienTheGreat // This creates the QFunction directly. 192*2027fb9dSSirAlienTheGreat CeedQFunctionCreateInterior(ceed, 1, build_mass, build_mass_loc, &qf_build); 193*2027fb9dSSirAlienTheGreat CeedQFunctionAddInput(qf_build, "dx", num_comp_x * dim, CEED_EVAL_GRAD); 194*2027fb9dSSirAlienTheGreat CeedQFunctionAddInput(qf_build, "weights", 1, CEED_EVAL_WEIGHT); 195*2027fb9dSSirAlienTheGreat CeedQFunctionAddOutput(qf_build, "qdata", 1, CEED_EVAL_NONE); 196*2027fb9dSSirAlienTheGreat CeedQFunctionSetContext(qf_build, build_ctx); 197*2027fb9dSSirAlienTheGreat } 198*2027fb9dSSirAlienTheGreat 199*2027fb9dSSirAlienTheGreat // Create the operator that builds the quadrature data for the mass operator. 200*2027fb9dSSirAlienTheGreat CeedOperator op_build; 201*2027fb9dSSirAlienTheGreat 202*2027fb9dSSirAlienTheGreat CeedOperatorCreate(ceed, qf_build, CEED_QFUNCTION_NONE, CEED_QFUNCTION_NONE, &op_build); 203*2027fb9dSSirAlienTheGreat CeedOperatorSetField(op_build, "dx", mesh_restriction, mesh_basis, CEED_VECTOR_ACTIVE); 204*2027fb9dSSirAlienTheGreat CeedOperatorSetField(op_build, "weights", CEED_ELEMRESTRICTION_NONE, mesh_basis, CEED_VECTOR_NONE); 205*2027fb9dSSirAlienTheGreat CeedOperatorSetField(op_build, "qdata", q_data_restriction, CEED_BASIS_NONE, CEED_VECTOR_ACTIVE); 206*2027fb9dSSirAlienTheGreat 207*2027fb9dSSirAlienTheGreat // Compute the quadrature data for the mass operator. 208*2027fb9dSSirAlienTheGreat CeedVector q_data; 209*2027fb9dSSirAlienTheGreat CeedInt elem_qpts = CeedIntPow(num_qpts, dim); 210*2027fb9dSSirAlienTheGreat CeedInt num_elem = 1; 211*2027fb9dSSirAlienTheGreat 212*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) num_elem *= num_xyz[d]; 213*2027fb9dSSirAlienTheGreat CeedVectorCreate(ceed, num_elem * elem_qpts, &q_data); 214*2027fb9dSSirAlienTheGreat CeedOperatorApply(op_build, mesh_coords, q_data, CEED_REQUEST_IMMEDIATE); 215*2027fb9dSSirAlienTheGreat 216*2027fb9dSSirAlienTheGreat // Create the QFunction that defines the action of the mass operator. 217*2027fb9dSSirAlienTheGreat CeedQFunction qf_apply; 218*2027fb9dSSirAlienTheGreat 219*2027fb9dSSirAlienTheGreat if (gallery) { 220*2027fb9dSSirAlienTheGreat // This creates the QFunction via the gallery. 221*2027fb9dSSirAlienTheGreat CeedQFunctionCreateInteriorByName(ceed, "MassApply", &qf_apply); 222*2027fb9dSSirAlienTheGreat } else { 223*2027fb9dSSirAlienTheGreat // This creates the QFunction directly. 224*2027fb9dSSirAlienTheGreat CeedQFunctionCreateInterior(ceed, 1, apply_mass, apply_mass_loc, &qf_apply); 225*2027fb9dSSirAlienTheGreat CeedQFunctionAddInput(qf_apply, "u", 1, CEED_EVAL_INTERP); 226*2027fb9dSSirAlienTheGreat CeedQFunctionAddInput(qf_apply, "qdata", 1, CEED_EVAL_NONE); 227*2027fb9dSSirAlienTheGreat CeedQFunctionAddOutput(qf_apply, "v", 1, CEED_EVAL_INTERP); 228*2027fb9dSSirAlienTheGreat } 229*2027fb9dSSirAlienTheGreat 230*2027fb9dSSirAlienTheGreat // Create the mass operator. 231*2027fb9dSSirAlienTheGreat CeedOperator op_apply; 232*2027fb9dSSirAlienTheGreat 233*2027fb9dSSirAlienTheGreat CeedOperatorCreate(ceed, qf_apply, CEED_QFUNCTION_NONE, CEED_QFUNCTION_NONE, &op_apply); 234*2027fb9dSSirAlienTheGreat CeedOperatorSetField(op_apply, "u", sol_restriction, sol_basis, CEED_VECTOR_ACTIVE); 235*2027fb9dSSirAlienTheGreat CeedOperatorSetField(op_apply, "qdata", q_data_restriction, CEED_BASIS_NONE, q_data); 236*2027fb9dSSirAlienTheGreat CeedOperatorSetField(op_apply, "v", sol_restriction, sol_basis, CEED_VECTOR_ACTIVE); 237*2027fb9dSSirAlienTheGreat 238*2027fb9dSSirAlienTheGreat // Create auxiliary solution-size vectors. 239*2027fb9dSSirAlienTheGreat CeedVector u, v; 240*2027fb9dSSirAlienTheGreat 241*2027fb9dSSirAlienTheGreat CeedVectorCreate(ceed, sol_size, &u); 242*2027fb9dSSirAlienTheGreat CeedVectorCreate(ceed, sol_size, &v); 243*2027fb9dSSirAlienTheGreat 244*2027fb9dSSirAlienTheGreat // Initialize 'u' with ones. 245*2027fb9dSSirAlienTheGreat CeedVectorSetValue(u, 1.0); 246*2027fb9dSSirAlienTheGreat 247*2027fb9dSSirAlienTheGreat // Compute the mesh volume using the mass operator: volume = 1^T \cdot M \cdot 1 248*2027fb9dSSirAlienTheGreat CeedOperatorApply(op_apply, u, v, CEED_REQUEST_IMMEDIATE); 249*2027fb9dSSirAlienTheGreat 250*2027fb9dSSirAlienTheGreat // Benchmark runs 251*2027fb9dSSirAlienTheGreat if (!test && benchmark) { 252*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 253*2027fb9dSSirAlienTheGreat printf(" Executing %d benchmarking runs...\n", benchmark); 254*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 255*2027fb9dSSirAlienTheGreat } 256*2027fb9dSSirAlienTheGreat for (CeedInt i = 0; i < benchmark; i++) { 257*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 258*2027fb9dSSirAlienTheGreat CeedOperatorApply(op_apply, u, v, CEED_REQUEST_IMMEDIATE); 259*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 260*2027fb9dSSirAlienTheGreat } 261*2027fb9dSSirAlienTheGreat 262*2027fb9dSSirAlienTheGreat // Compute and print the sum of the entries of 'v' giving the mesh volume. 263*2027fb9dSSirAlienTheGreat CeedScalar volume = 0.; 264*2027fb9dSSirAlienTheGreat 265*2027fb9dSSirAlienTheGreat { 266*2027fb9dSSirAlienTheGreat const CeedScalar *v_array; 267*2027fb9dSSirAlienTheGreat 268*2027fb9dSSirAlienTheGreat CeedVectorGetArrayRead(v, CEED_MEM_HOST, &v_array); 269*2027fb9dSSirAlienTheGreat for (CeedInt i = 0; i < sol_size; i++) volume += v_array[i]; 270*2027fb9dSSirAlienTheGreat CeedVectorRestoreArrayRead(v, &v_array); 271*2027fb9dSSirAlienTheGreat } 272*2027fb9dSSirAlienTheGreat if (!test) { 273*2027fb9dSSirAlienTheGreat // LCOV_EXCL_START 274*2027fb9dSSirAlienTheGreat printf(" done.\n"); 275*2027fb9dSSirAlienTheGreat printf("Exact mesh volume : % .14g\n", exact_volume); 276*2027fb9dSSirAlienTheGreat printf("Computed mesh volume : % .14g\n", volume); 277*2027fb9dSSirAlienTheGreat printf("Volume error : % .14g\n", volume - exact_volume); 278*2027fb9dSSirAlienTheGreat // LCOV_EXCL_STOP 279*2027fb9dSSirAlienTheGreat } else { 280*2027fb9dSSirAlienTheGreat CeedScalar tol = (dim == 1 ? 200. * CEED_EPSILON : dim == 2 ? 1E-5 : 1E-5); 281*2027fb9dSSirAlienTheGreat 282*2027fb9dSSirAlienTheGreat if (fabs(volume - exact_volume) > tol) printf("Volume error : % .1e\n", volume - exact_volume); 283*2027fb9dSSirAlienTheGreat } 284*2027fb9dSSirAlienTheGreat 285*2027fb9dSSirAlienTheGreat // Free dynamically allocated memory. 286*2027fb9dSSirAlienTheGreat CeedVectorDestroy(&u); 287*2027fb9dSSirAlienTheGreat CeedVectorDestroy(&v); 288*2027fb9dSSirAlienTheGreat CeedVectorDestroy(&q_data); 289*2027fb9dSSirAlienTheGreat CeedVectorDestroy(&mesh_coords); 290*2027fb9dSSirAlienTheGreat CeedOperatorDestroy(&op_apply); 291*2027fb9dSSirAlienTheGreat CeedQFunctionDestroy(&qf_apply); 292*2027fb9dSSirAlienTheGreat CeedQFunctionContextDestroy(&build_ctx); 293*2027fb9dSSirAlienTheGreat CeedOperatorDestroy(&op_build); 294*2027fb9dSSirAlienTheGreat CeedQFunctionDestroy(&qf_build); 295*2027fb9dSSirAlienTheGreat CeedElemRestrictionDestroy(&sol_restriction); 296*2027fb9dSSirAlienTheGreat CeedElemRestrictionDestroy(&mesh_restriction); 297*2027fb9dSSirAlienTheGreat CeedElemRestrictionDestroy(&q_data_restriction); 298*2027fb9dSSirAlienTheGreat CeedBasisDestroy(&sol_basis); 299*2027fb9dSSirAlienTheGreat CeedBasisDestroy(&mesh_basis); 300*2027fb9dSSirAlienTheGreat CeedDestroy(&ceed); 301*2027fb9dSSirAlienTheGreat return 0; 302*2027fb9dSSirAlienTheGreat } 303*2027fb9dSSirAlienTheGreat 304*2027fb9dSSirAlienTheGreat int GetCartesianMeshSize(CeedInt dim, CeedInt degree, CeedInt prob_size, CeedInt num_xyz[dim]) { 305*2027fb9dSSirAlienTheGreat // Use the approximate formula: 306*2027fb9dSSirAlienTheGreat // prob_size ~ num_elem * degree^dim 307*2027fb9dSSirAlienTheGreat CeedInt num_elem = prob_size / CeedIntPow(degree, dim); 308*2027fb9dSSirAlienTheGreat CeedInt s = 0; // find s: num_elem/2 < 2^s <= num_elem 309*2027fb9dSSirAlienTheGreat 310*2027fb9dSSirAlienTheGreat while (num_elem > 1) { 311*2027fb9dSSirAlienTheGreat num_elem /= 2; 312*2027fb9dSSirAlienTheGreat s++; 313*2027fb9dSSirAlienTheGreat } 314*2027fb9dSSirAlienTheGreat CeedInt r = s % dim; 315*2027fb9dSSirAlienTheGreat 316*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) { 317*2027fb9dSSirAlienTheGreat CeedInt sd = s / dim; 318*2027fb9dSSirAlienTheGreat 319*2027fb9dSSirAlienTheGreat if (r > 0) { 320*2027fb9dSSirAlienTheGreat sd++; 321*2027fb9dSSirAlienTheGreat r--; 322*2027fb9dSSirAlienTheGreat } 323*2027fb9dSSirAlienTheGreat num_xyz[d] = 1 << sd; 324*2027fb9dSSirAlienTheGreat } 325*2027fb9dSSirAlienTheGreat return 0; 326*2027fb9dSSirAlienTheGreat } 327*2027fb9dSSirAlienTheGreat 328*2027fb9dSSirAlienTheGreat int BuildCartesianRestriction(Ceed ceed, CeedInt dim, CeedInt num_xyz[dim], CeedInt degree, CeedInt num_comp, CeedInt *size, CeedInt num_qpts, 329*2027fb9dSSirAlienTheGreat CeedElemRestriction *restriction, CeedElemRestriction *q_data_restriction) { 330*2027fb9dSSirAlienTheGreat CeedInt p = degree + 1; 331*2027fb9dSSirAlienTheGreat CeedInt num_nodes = CeedIntPow(p, dim); // number of scalar nodes per element 332*2027fb9dSSirAlienTheGreat CeedInt elem_qpts = CeedIntPow(num_qpts, dim); // number of qpts per element 333*2027fb9dSSirAlienTheGreat CeedInt nd[3], num_elem = 1, scalar_size = 1; 334*2027fb9dSSirAlienTheGreat 335*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) { 336*2027fb9dSSirAlienTheGreat num_elem *= num_xyz[d]; 337*2027fb9dSSirAlienTheGreat nd[d] = num_xyz[d] * (p - 1) + 1; 338*2027fb9dSSirAlienTheGreat scalar_size *= nd[d]; 339*2027fb9dSSirAlienTheGreat } 340*2027fb9dSSirAlienTheGreat *size = scalar_size * num_comp; 341*2027fb9dSSirAlienTheGreat // elem: 0 1 n-1 342*2027fb9dSSirAlienTheGreat // |---*-...-*---|---*-...-*---|- ... -|--...--| 343*2027fb9dSSirAlienTheGreat // num_nodes: 0 1 p-1 p p+1 2*p n*p 344*2027fb9dSSirAlienTheGreat CeedInt *elem_nodes = malloc(sizeof(CeedInt) * num_elem * num_nodes); 345*2027fb9dSSirAlienTheGreat 346*2027fb9dSSirAlienTheGreat for (CeedInt e = 0; e < num_elem; e++) { 347*2027fb9dSSirAlienTheGreat CeedInt e_xyz[3] = {1, 1, 1}, re = e; 348*2027fb9dSSirAlienTheGreat 349*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) { 350*2027fb9dSSirAlienTheGreat e_xyz[d] = re % num_xyz[d]; 351*2027fb9dSSirAlienTheGreat re /= num_xyz[d]; 352*2027fb9dSSirAlienTheGreat } 353*2027fb9dSSirAlienTheGreat CeedInt *local_elem_nodes = elem_nodes + e * num_nodes; 354*2027fb9dSSirAlienTheGreat 355*2027fb9dSSirAlienTheGreat for (CeedInt l_nodes = 0; l_nodes < num_nodes; l_nodes++) { 356*2027fb9dSSirAlienTheGreat CeedInt g_nodes = 0, g_nodes_stride = 1, r_nodes = l_nodes; 357*2027fb9dSSirAlienTheGreat 358*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) { 359*2027fb9dSSirAlienTheGreat g_nodes += (e_xyz[d] * (p - 1) + r_nodes % p) * g_nodes_stride; 360*2027fb9dSSirAlienTheGreat g_nodes_stride *= nd[d]; 361*2027fb9dSSirAlienTheGreat r_nodes /= p; 362*2027fb9dSSirAlienTheGreat } 363*2027fb9dSSirAlienTheGreat local_elem_nodes[l_nodes] = g_nodes; 364*2027fb9dSSirAlienTheGreat } 365*2027fb9dSSirAlienTheGreat } 366*2027fb9dSSirAlienTheGreat CeedElemRestrictionCreate(ceed, num_elem, num_nodes, num_comp, scalar_size, num_comp * scalar_size, CEED_MEM_HOST, CEED_COPY_VALUES, elem_nodes, 367*2027fb9dSSirAlienTheGreat restriction); 368*2027fb9dSSirAlienTheGreat if (q_data_restriction) { 369*2027fb9dSSirAlienTheGreat CeedElemRestrictionCreateStrided(ceed, num_elem, elem_qpts, num_comp, num_comp * elem_qpts * num_elem, CEED_STRIDES_BACKEND, q_data_restriction); 370*2027fb9dSSirAlienTheGreat } 371*2027fb9dSSirAlienTheGreat free(elem_nodes); 372*2027fb9dSSirAlienTheGreat return 0; 373*2027fb9dSSirAlienTheGreat } 374*2027fb9dSSirAlienTheGreat 375*2027fb9dSSirAlienTheGreat int SetCartesianMeshCoords(CeedInt dim, CeedInt num_xyz[dim], CeedInt mesh_degree, CeedVector mesh_coords) { 376*2027fb9dSSirAlienTheGreat CeedInt p = mesh_degree + 1; 377*2027fb9dSSirAlienTheGreat CeedInt nd[3], scalar_size = 1; 378*2027fb9dSSirAlienTheGreat 379*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) { 380*2027fb9dSSirAlienTheGreat nd[d] = num_xyz[d] * (p - 1) + 1; 381*2027fb9dSSirAlienTheGreat scalar_size *= nd[d]; 382*2027fb9dSSirAlienTheGreat } 383*2027fb9dSSirAlienTheGreat CeedScalar *coords; 384*2027fb9dSSirAlienTheGreat 385*2027fb9dSSirAlienTheGreat CeedVectorGetArrayWrite(mesh_coords, CEED_MEM_HOST, &coords); 386*2027fb9dSSirAlienTheGreat CeedScalar *nodes = malloc(sizeof(CeedScalar) * p); 387*2027fb9dSSirAlienTheGreat 388*2027fb9dSSirAlienTheGreat // The H1 basis uses Lobatto quadrature points as nodes. 389*2027fb9dSSirAlienTheGreat CeedLobattoQuadrature(p, nodes, NULL); // nodes are in [-1,1] 390*2027fb9dSSirAlienTheGreat for (CeedInt i = 0; i < p; i++) nodes[i] = 0.5 + 0.5 * nodes[i]; 391*2027fb9dSSirAlienTheGreat for (CeedInt gs_nodes = 0; gs_nodes < scalar_size; gs_nodes++) { 392*2027fb9dSSirAlienTheGreat CeedInt r_nodes = gs_nodes; 393*2027fb9dSSirAlienTheGreat 394*2027fb9dSSirAlienTheGreat for (CeedInt d = 0; d < dim; d++) { 395*2027fb9dSSirAlienTheGreat CeedInt d_1d = r_nodes % nd[d]; 396*2027fb9dSSirAlienTheGreat 397*2027fb9dSSirAlienTheGreat coords[gs_nodes + scalar_size * d] = ((d_1d / (p - 1)) + nodes[d_1d % (p - 1)]) / num_xyz[d]; 398*2027fb9dSSirAlienTheGreat r_nodes /= nd[d]; 399*2027fb9dSSirAlienTheGreat } 400*2027fb9dSSirAlienTheGreat } 401*2027fb9dSSirAlienTheGreat free(nodes); 402*2027fb9dSSirAlienTheGreat CeedVectorRestoreArray(mesh_coords, &coords); 403*2027fb9dSSirAlienTheGreat return 0; 404*2027fb9dSSirAlienTheGreat } 405*2027fb9dSSirAlienTheGreat 406*2027fb9dSSirAlienTheGreat #ifndef M_PI 407*2027fb9dSSirAlienTheGreat #define M_PI 3.14159265358979323846 408*2027fb9dSSirAlienTheGreat #define M_PI_2 1.57079632679489661923 409*2027fb9dSSirAlienTheGreat #endif 410*2027fb9dSSirAlienTheGreat 411*2027fb9dSSirAlienTheGreat CeedScalar TransformMeshCoords(CeedInt dim, CeedInt mesh_size, CeedVector mesh_coords) { 412*2027fb9dSSirAlienTheGreat CeedScalar exact_volume; 413*2027fb9dSSirAlienTheGreat CeedScalar *coords; 414*2027fb9dSSirAlienTheGreat 415*2027fb9dSSirAlienTheGreat CeedVectorGetArray(mesh_coords, CEED_MEM_HOST, &coords); 416*2027fb9dSSirAlienTheGreat if (dim == 1) { 417*2027fb9dSSirAlienTheGreat for (CeedInt i = 0; i < mesh_size; i++) { 418*2027fb9dSSirAlienTheGreat // map [0,1] to [0,1] varying the mesh density 419*2027fb9dSSirAlienTheGreat coords[i] = 0.5 + 1. / sqrt(3.) * sin((2. / 3.) * M_PI * (coords[i] - 0.5)); 420*2027fb9dSSirAlienTheGreat } 421*2027fb9dSSirAlienTheGreat exact_volume = 1.; 422*2027fb9dSSirAlienTheGreat } else { 423*2027fb9dSSirAlienTheGreat CeedInt num_nodes = mesh_size / dim; 424*2027fb9dSSirAlienTheGreat 425*2027fb9dSSirAlienTheGreat for (CeedInt i = 0; i < num_nodes; i++) { 426*2027fb9dSSirAlienTheGreat // map (x,y) from [0,1]x[0,1] to the quarter annulus with polar 427*2027fb9dSSirAlienTheGreat // coordinates, (r,phi) in [1,2]x[0,pi/2] with area = 3/4*pi 428*2027fb9dSSirAlienTheGreat CeedScalar u = coords[i], v = coords[i + num_nodes]; 429*2027fb9dSSirAlienTheGreat 430*2027fb9dSSirAlienTheGreat u = 1. + u; 431*2027fb9dSSirAlienTheGreat v = M_PI_2 * v; 432*2027fb9dSSirAlienTheGreat coords[i] = u * cos(v); 433*2027fb9dSSirAlienTheGreat coords[i + num_nodes] = u * sin(v); 434*2027fb9dSSirAlienTheGreat } 435*2027fb9dSSirAlienTheGreat exact_volume = 3. / 4. * M_PI; 436*2027fb9dSSirAlienTheGreat } 437*2027fb9dSSirAlienTheGreat CeedVectorRestoreArray(mesh_coords, &coords); 438*2027fb9dSSirAlienTheGreat return exact_volume; 439*2027fb9dSSirAlienTheGreat } 440