// Copyright (c) 2017-2024, Lawrence Livermore National Security, LLC and other CEED contributors. // All Rights Reserved. See the top-level LICENSE and NOTICE files for details. // // SPDX-License-Identifier: BSD-2-Clause // // This file is part of CEED: http://github.com/ceed /// @file /// Geometric factors (2D) for Navier-Stokes example using PETSc #include #include "setupgeo_helpers.h" #include "utils.h" // ***************************************************************************** // This QFunction sets up the geometric factors required for integration and coordinate transformations // // Reference (parent) coordinates: X // Physical (current) coordinates: x // Change of coordinate matrix: dxdX_{i,j} = x_{i,j} (indicial notation) // Inverse of change of coordinate matrix: dXdx_{i,j} = (detJ^-1) * X_{i,j} // // All quadrature data is stored in 10 field vector of quadrature data. // // We require the determinant of the Jacobian to properly compute integrals of the form: int( v u ) // // Determinant of Jacobian: // detJ = J11*J22 - J21*J12 // Jij = Jacobian entry ij // // Stored: w detJ // in q_data[0] // // We require the transpose of the inverse of the Jacobian to properly compute integrals of the form: int( gradv u ) // // Inverse of Jacobian: // dXdx_i,j = Aij / detJ // Aij = Adjugate ij // // Stored: Aij / detJ // in q_data[1:4] as // (detJ^-1) * [A11 A12] // [A21 A22] // ***************************************************************************** CEED_QFUNCTION(Setup2d)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { const CeedScalar(*J)[2][CEED_Q_VLA] = (const CeedScalar(*)[2][CEED_Q_VLA])in[0]; const CeedScalar(*w) = in[1]; CeedScalar(*q_data) = out[0]; CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { CeedScalar dXdx[2][2], detJ; InvertMappingJacobian_2D(Q, i, J, dXdx, &detJ); const CeedScalar wdetJ = w[i] * detJ; StoredValuesPack(Q, i, 0, 1, &wdetJ, q_data); StoredValuesPack(Q, i, 1, 4, (const CeedScalar *)dXdx, q_data); } return 0; } // ***************************************************************************** // This QFunction sets up the geometric factor required for integration when reference coordinates are in 1D and the physical coordinates are in 2D // // Reference (parent) 1D coordinates: X // Physical (current) 2D coordinates: x // Change of coordinate vector: // J1 = dx_1/dX // J2 = dx_2/dX // // detJb is the magnitude of (J1,J2) // // All quadrature data is stored in 3 field vector of quadrature data. // // We require the determinant of the Jacobian to properly compute integrals of the form: int( u v ) // // Stored: w detJb // in q_data_sur[0] // // Normal vector is given by the cross product of (J1,J2)/detJ and ẑ // // Stored: (J1,J2,0) x (0,0,1) / detJb // in q_data_sur[1:2] as // (detJb^-1) * [ J2 ] // [-J1 ] // ***************************************************************************** CEED_QFUNCTION(SetupBoundary2d)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { const CeedScalar(*J)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0]; const CeedScalar(*w) = in[1]; CeedScalar(*q_data_sur) = out[0]; CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { CeedScalar normal[2], detJb; NormalVectorFromdxdX_2D(Q, i, J, normal, &detJb); const CeedScalar wdetJ = w[i] * detJb; StoredValuesPack(Q, i, 0, 1, &wdetJ, q_data_sur); StoredValuesPack(Q, i, 1, 2, normal, q_data_sur); } return 0; } // ***************************************************************************** // This QFunction sets up the geometric factor required for integration when reference coordinates are in 2D and the physical coordinates are in 3D // // Reference (parent) 2D coordinates: X // Physical (current) 3D coordinates: x // Change of coordinate matrix: // dxdX_{i,j} = dx_i/dX_j (indicial notation) [3 * 2] // Inverse change of coordinate matrix: // dXdx_{i,j} = dX_i/dx_j (indicial notation) [2 * 3] // // (J1,J2,J3) is given by the cross product of the columns of dxdX_{i,j} // // detJb is the magnitude of (J1,J2,J3) // // dXdx is calculated via Moore–Penrose inverse: // // dX_i/dx_j = (dxdX^T dxdX)^(-1) dxdX // = (dx_l/dX_i * dx_l/dX_k)^(-1) dx_j/dX_k // // All quadrature data is stored in 10 field vector of quadrature data. // // We require the determinant of the Jacobian to properly compute integrals of // the form: int( u v ) // // Stored: w detJb // in q_data_sur[0] // // Normal vector = (J1,J2,J3) / detJb // // Stored: (J1,J2,J3) / detJb // // Stored: dXdx_{i,j} // in q_data_sur[1:6] as // [dXdx_11 dXdx_12 dXdx_13] // [dXdx_21 dXdx_22 dXdx_23] // ***************************************************************************** CEED_QFUNCTION(Setup2D_3Dcoords)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { const CeedScalar(*J)[3][CEED_Q_VLA] = (const CeedScalar(*)[3][CEED_Q_VLA])in[0]; const CeedScalar(*w) = in[1]; CeedScalar(*q_data_sur) = out[0]; CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { CeedScalar detJb, normal[3], dXdx[2][3]; NormalVectorFromdxdX_3D(Q, i, J, normal, &detJb); InvertBoundaryMappingJacobian_3D(Q, i, J, dXdx); const CeedScalar wdetJ = w[i] * detJb; StoredValuesPack(Q, i, 0, 1, &wdetJ, q_data_sur); StoredValuesPack(Q, i, 1, 6, (const CeedScalar *)dXdx, q_data_sur); } return 0; }