// Copyright (c) 2017-2026, 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 #include #include #include #include #include #include #include "../cuda/ceed-cuda-common.h" #include "../cuda/ceed-cuda-compile.h" #include "ceed-cuda-ref.h" //------------------------------------------------------------------------------ // Basis apply - tensor //------------------------------------------------------------------------------ static int CeedBasisApplyCore_Cuda(CeedBasis basis, bool apply_add, const CeedInt num_elem, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector u, CeedVector v) { Ceed ceed; CeedInt Q_1d, dim; const CeedInt is_transpose = t_mode == CEED_TRANSPOSE; const int max_block_size = 32; const CeedScalar *d_u; CeedScalar *d_v; CeedBasis_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedBasisGetData(basis, &data)); // Get read/write access to u, v if (u != CEED_VECTOR_NONE) CeedCallBackend(CeedVectorGetArrayRead(u, CEED_MEM_DEVICE, &d_u)); else CeedCheck(eval_mode == CEED_EVAL_WEIGHT, ceed, CEED_ERROR_BACKEND, "An input vector is required for this CeedEvalMode"); if (apply_add) { CeedCallBackend(CeedVectorGetArray(v, CEED_MEM_DEVICE, &d_v)); } else { // Clear v for transpose operation if (is_transpose) CeedCallBackend(CeedVectorSetValue(v, 0.0)); CeedCallBackend(CeedVectorGetArrayWrite(v, CEED_MEM_DEVICE, &d_v)); } CeedCallBackend(CeedBasisGetNumQuadraturePoints1D(basis, &Q_1d)); CeedCallBackend(CeedBasisGetDimension(basis, &dim)); // Basis action switch (eval_mode) { case CEED_EVAL_INTERP: { void *interp_args[] = {(void *)&num_elem, (void *)&is_transpose, &data->d_interp_1d, &d_u, &d_v}; const CeedInt block_size = CeedIntMin(CeedIntPow(Q_1d, dim), max_block_size); CeedCallBackend(CeedRunKernel_Cuda(ceed, data->Interp, num_elem, block_size, interp_args)); } break; case CEED_EVAL_GRAD: { void *grad_args[] = {(void *)&num_elem, (void *)&is_transpose, &data->d_interp_1d, &data->d_grad_1d, &d_u, &d_v}; const CeedInt block_size = max_block_size; CeedCallBackend(CeedRunKernel_Cuda(ceed, data->Grad, num_elem, block_size, grad_args)); } break; case CEED_EVAL_WEIGHT: { CeedCheck(data->d_q_weight_1d, ceed, CEED_ERROR_BACKEND, "%s not supported; q_weights_1d not set", CeedEvalModes[eval_mode]); void *weight_args[] = {(void *)&num_elem, (void *)&data->d_q_weight_1d, &d_v}; const int block_size_x = Q_1d; const int block_size_y = dim >= 2 ? Q_1d : 1; CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->Weight, num_elem, block_size_x, block_size_y, 1, weight_args)); } break; case CEED_EVAL_NONE: /* handled separately below */ break; // LCOV_EXCL_START case CEED_EVAL_DIV: case CEED_EVAL_CURL: return CeedError(ceed, CEED_ERROR_BACKEND, "%s not supported", CeedEvalModes[eval_mode]); // LCOV_EXCL_STOP } // Restore vectors, cover CEED_EVAL_NONE CeedCallBackend(CeedVectorRestoreArray(v, &d_v)); if (eval_mode == CEED_EVAL_NONE) CeedCallBackend(CeedVectorSetArray(v, CEED_MEM_DEVICE, CEED_COPY_VALUES, (CeedScalar *)d_u)); if (eval_mode != CEED_EVAL_WEIGHT) CeedCallBackend(CeedVectorRestoreArrayRead(u, &d_u)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } static int CeedBasisApply_Cuda(CeedBasis basis, const CeedInt num_elem, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector u, CeedVector v) { CeedCallBackend(CeedBasisApplyCore_Cuda(basis, false, num_elem, t_mode, eval_mode, u, v)); return CEED_ERROR_SUCCESS; } static int CeedBasisApplyAdd_Cuda(CeedBasis basis, const CeedInt num_elem, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector u, CeedVector v) { CeedCallBackend(CeedBasisApplyCore_Cuda(basis, true, num_elem, t_mode, eval_mode, u, v)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Basis apply - tensor AtPoints //------------------------------------------------------------------------------ static int CeedBasisApplyAtPointsCore_Cuda(CeedBasis basis, bool apply_add, const CeedInt num_elem, const CeedInt *num_points, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector x_ref, CeedVector u, CeedVector v) { Ceed ceed; CeedInt Q_1d, dim, max_num_points = num_points[0]; const CeedInt is_transpose = t_mode == CEED_TRANSPOSE; const int max_block_size = 32; const CeedScalar *d_x, *d_u; CeedScalar *d_v; CeedBasis_Cuda *data; CeedCallBackend(CeedBasisGetData(basis, &data)); CeedCallBackend(CeedBasisGetNumQuadraturePoints1D(basis, &Q_1d)); CeedCallBackend(CeedBasisGetDimension(basis, &dim)); // Weight handled separately if (eval_mode == CEED_EVAL_WEIGHT) { CeedCallBackend(CeedVectorSetValue(v, 1.0)); return CEED_ERROR_SUCCESS; } CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); // Check padded to uniform number of points per elem for (CeedInt i = 1; i < num_elem; i++) max_num_points = CeedIntMax(max_num_points, num_points[i]); { CeedInt num_comp, q_comp; CeedSize len, len_required; CeedCallBackend(CeedBasisGetNumComponents(basis, &num_comp)); CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, eval_mode, &q_comp)); CeedCallBackend(CeedVectorGetLength(is_transpose ? u : v, &len)); len_required = (CeedSize)num_comp * (CeedSize)q_comp * (CeedSize)num_elem * (CeedSize)max_num_points; CeedCheck(len >= len_required, ceed, CEED_ERROR_BACKEND, "Vector at points must be padded to the same number of points in each element for BasisApplyAtPoints on GPU backends." " Found %" CeedSize_FMT ", Required %" CeedSize_FMT, len, len_required); } // Move num_points array to device if (is_transpose) { const CeedInt num_bytes = num_elem * sizeof(CeedInt); if (num_elem != data->num_elem_at_points) { data->num_elem_at_points = num_elem; if (data->d_points_per_elem) CeedCallCuda(ceed, cudaFree(data->d_points_per_elem)); CeedCallCuda(ceed, cudaMalloc((void **)&data->d_points_per_elem, num_bytes)); CeedCallBackend(CeedFree(&data->h_points_per_elem)); CeedCallBackend(CeedCalloc(num_elem, &data->h_points_per_elem)); } if (memcmp(data->h_points_per_elem, num_points, num_bytes)) { memcpy(data->h_points_per_elem, num_points, num_bytes); CeedCallCuda(ceed, cudaMemcpy(data->d_points_per_elem, num_points, num_bytes, cudaMemcpyHostToDevice)); } } // Build kernels if needed if (data->num_points != max_num_points) { CeedInt P_1d; CeedCallBackend(CeedBasisGetNumNodes1D(basis, &P_1d)); data->num_points = max_num_points; // -- Create interp matrix to Chebyshev coefficients if (!data->d_chebyshev_interp_1d) { CeedSize interp_bytes; CeedScalar *chebyshev_interp_1d; interp_bytes = P_1d * Q_1d * sizeof(CeedScalar); CeedCallBackend(CeedCalloc(P_1d * Q_1d, &chebyshev_interp_1d)); CeedCallBackend(CeedBasisGetChebyshevInterp1D(basis, chebyshev_interp_1d)); CeedCallCuda(ceed, cudaMalloc((void **)&data->d_chebyshev_interp_1d, interp_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_chebyshev_interp_1d, chebyshev_interp_1d, interp_bytes, cudaMemcpyHostToDevice)); CeedCallBackend(CeedFree(&chebyshev_interp_1d)); } // -- Compile kernels const char basis_kernel_source[] = "// AtPoints basis source\n#include \n"; CeedInt num_comp; if (data->moduleAtPoints) CeedCallCuda(ceed, cuModuleUnload(data->moduleAtPoints)); CeedCallBackend(CeedBasisGetNumComponents(basis, &num_comp)); CeedCallBackend(CeedCompile_Cuda(ceed, basis_kernel_source, &data->moduleAtPoints, 9, "BASIS_Q_1D", Q_1d, "BASIS_P_1D", P_1d, "BASIS_BUF_LEN", Q_1d * CeedIntPow(Q_1d > P_1d ? Q_1d : P_1d, dim - 1), "BASIS_DIM", dim, "BASIS_NUM_COMP", num_comp, "BASIS_NUM_NODES", CeedIntPow(P_1d, dim), "BASIS_NUM_QPTS", CeedIntPow(Q_1d, dim), "BASIS_NUM_PTS", max_num_points, "POINTS_BUFF_LEN", CeedIntPow(Q_1d, dim - 1))); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->moduleAtPoints, "InterpAtPoints", &data->InterpAtPoints)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->moduleAtPoints, "InterpTransposeAtPoints", &data->InterpTransposeAtPoints)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->moduleAtPoints, "GradAtPoints", &data->GradAtPoints)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->moduleAtPoints, "GradTransposeAtPoints", &data->GradTransposeAtPoints)); } // Get read/write access to u, v CeedCallBackend(CeedVectorGetArrayRead(x_ref, CEED_MEM_DEVICE, &d_x)); if (u != CEED_VECTOR_NONE) CeedCallBackend(CeedVectorGetArrayRead(u, CEED_MEM_DEVICE, &d_u)); else CeedCheck(eval_mode == CEED_EVAL_WEIGHT, ceed, CEED_ERROR_BACKEND, "An input vector is required for this CeedEvalMode"); if (apply_add) { CeedCallBackend(CeedVectorGetArray(v, CEED_MEM_DEVICE, &d_v)); } else { // Clear v for transpose operation if (is_transpose) CeedCallBackend(CeedVectorSetValue(v, 0.0)); CeedCallBackend(CeedVectorGetArrayWrite(v, CEED_MEM_DEVICE, &d_v)); } // Basis action switch (eval_mode) { case CEED_EVAL_INTERP: { void *interp_args[] = {(void *)&num_elem, &data->d_chebyshev_interp_1d, &data->d_points_per_elem, &d_x, &d_u, &d_v}; const CeedInt block_size = CeedIntMin(CeedIntPow(Q_1d, dim), max_block_size); CeedCallBackend(CeedRunKernel_Cuda(ceed, is_transpose ? data->InterpTransposeAtPoints : data->InterpAtPoints, num_elem, block_size, interp_args)); } break; case CEED_EVAL_GRAD: { void *grad_args[] = {(void *)&num_elem, &data->d_chebyshev_interp_1d, &data->d_points_per_elem, &d_x, &d_u, &d_v}; const CeedInt block_size = CeedIntMin(CeedIntPow(Q_1d, dim), max_block_size); CeedCallBackend(CeedRunKernel_Cuda(ceed, is_transpose ? data->GradTransposeAtPoints : data->GradAtPoints, num_elem, block_size, grad_args)); } break; case CEED_EVAL_WEIGHT: case CEED_EVAL_NONE: /* handled separately below */ break; // LCOV_EXCL_START case CEED_EVAL_DIV: case CEED_EVAL_CURL: return CeedError(ceed, CEED_ERROR_BACKEND, "%s not supported", CeedEvalModes[eval_mode]); // LCOV_EXCL_STOP } // Restore vectors, cover CEED_EVAL_NONE CeedCallBackend(CeedVectorRestoreArrayRead(x_ref, &d_x)); CeedCallBackend(CeedVectorRestoreArray(v, &d_v)); if (eval_mode == CEED_EVAL_NONE) CeedCallBackend(CeedVectorSetArray(v, CEED_MEM_DEVICE, CEED_COPY_VALUES, (CeedScalar *)d_u)); if (eval_mode != CEED_EVAL_WEIGHT) CeedCallBackend(CeedVectorRestoreArrayRead(u, &d_u)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } static int CeedBasisApplyAtPoints_Cuda(CeedBasis basis, const CeedInt num_elem, const CeedInt *num_points, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector x_ref, CeedVector u, CeedVector v) { CeedCallBackend(CeedBasisApplyAtPointsCore_Cuda(basis, false, num_elem, num_points, t_mode, eval_mode, x_ref, u, v)); return CEED_ERROR_SUCCESS; } static int CeedBasisApplyAddAtPoints_Cuda(CeedBasis basis, const CeedInt num_elem, const CeedInt *num_points, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector x_ref, CeedVector u, CeedVector v) { CeedCallBackend(CeedBasisApplyAtPointsCore_Cuda(basis, true, num_elem, num_points, t_mode, eval_mode, x_ref, u, v)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Basis apply - non-tensor //------------------------------------------------------------------------------ static int CeedBasisApplyNonTensorCore_Cuda(CeedBasis basis, bool apply_add, const CeedInt num_elem, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector u, CeedVector v) { Ceed ceed; CeedInt num_nodes, num_qpts; const CeedInt is_transpose = t_mode == CEED_TRANSPOSE; const int elems_per_block = 1; const int grid = CeedDivUpInt(num_elem, elems_per_block); const CeedScalar *d_u; CeedScalar *d_v; CeedBasisNonTensor_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedBasisGetData(basis, &data)); CeedCallBackend(CeedBasisGetNumQuadraturePoints(basis, &num_qpts)); CeedCallBackend(CeedBasisGetNumNodes(basis, &num_nodes)); // Get read/write access to u, v if (u != CEED_VECTOR_NONE) CeedCallBackend(CeedVectorGetArrayRead(u, CEED_MEM_DEVICE, &d_u)); else CeedCheck(eval_mode == CEED_EVAL_WEIGHT, ceed, CEED_ERROR_BACKEND, "An input vector is required for this CeedEvalMode"); if (apply_add) { CeedCallBackend(CeedVectorGetArray(v, CEED_MEM_DEVICE, &d_v)); } else { // Clear v for transpose operation if (is_transpose) CeedCallBackend(CeedVectorSetValue(v, 0.0)); CeedCallBackend(CeedVectorGetArrayWrite(v, CEED_MEM_DEVICE, &d_v)); } // Apply basis operation switch (eval_mode) { case CEED_EVAL_INTERP: { void *interp_args[] = {(void *)&num_elem, &data->d_interp, &d_u, &d_v}; const int block_size_x = is_transpose ? num_nodes : num_qpts; if (is_transpose) { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->InterpTranspose, grid, block_size_x, 1, elems_per_block, interp_args)); } else { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->Interp, grid, block_size_x, 1, elems_per_block, interp_args)); } } break; case CEED_EVAL_GRAD: { void *grad_args[] = {(void *)&num_elem, &data->d_grad, &d_u, &d_v}; const int block_size_x = is_transpose ? num_nodes : num_qpts; if (is_transpose) { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->DerivTranspose, grid, block_size_x, 1, elems_per_block, grad_args)); } else { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->Deriv, grid, block_size_x, 1, elems_per_block, grad_args)); } } break; case CEED_EVAL_DIV: { void *div_args[] = {(void *)&num_elem, &data->d_div, &d_u, &d_v}; const int block_size_x = is_transpose ? num_nodes : num_qpts; if (is_transpose) { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->DerivTranspose, grid, block_size_x, 1, elems_per_block, div_args)); } else { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->Deriv, grid, block_size_x, 1, elems_per_block, div_args)); } } break; case CEED_EVAL_CURL: { void *curl_args[] = {(void *)&num_elem, &data->d_curl, &d_u, &d_v}; const int block_size_x = is_transpose ? num_nodes : num_qpts; if (is_transpose) { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->DerivTranspose, grid, block_size_x, 1, elems_per_block, curl_args)); } else { CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->Deriv, grid, block_size_x, 1, elems_per_block, curl_args)); } } break; case CEED_EVAL_WEIGHT: { CeedCheck(data->d_q_weight, ceed, CEED_ERROR_BACKEND, "%s not supported; q_weights not set", CeedEvalModes[eval_mode]); void *weight_args[] = {(void *)&num_elem, (void *)&data->d_q_weight, &d_v}; CeedCallBackend(CeedRunKernelDim_Cuda(ceed, data->Weight, grid, num_qpts, 1, elems_per_block, weight_args)); } break; case CEED_EVAL_NONE: /* handled separately below */ break; } // Restore vectors, cover CEED_EVAL_NONE CeedCallBackend(CeedVectorRestoreArray(v, &d_v)); if (eval_mode == CEED_EVAL_NONE) CeedCallBackend(CeedVectorSetArray(v, CEED_MEM_DEVICE, CEED_COPY_VALUES, (CeedScalar *)d_u)); if (eval_mode != CEED_EVAL_WEIGHT) CeedCallBackend(CeedVectorRestoreArrayRead(u, &d_u)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } static int CeedBasisApplyNonTensor_Cuda(CeedBasis basis, const CeedInt num_elem, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector u, CeedVector v) { CeedCallBackend(CeedBasisApplyNonTensorCore_Cuda(basis, false, num_elem, t_mode, eval_mode, u, v)); return CEED_ERROR_SUCCESS; } static int CeedBasisApplyAddNonTensor_Cuda(CeedBasis basis, const CeedInt num_elem, CeedTransposeMode t_mode, CeedEvalMode eval_mode, CeedVector u, CeedVector v) { CeedCallBackend(CeedBasisApplyNonTensorCore_Cuda(basis, true, num_elem, t_mode, eval_mode, u, v)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Destroy tensor basis //------------------------------------------------------------------------------ static int CeedBasisDestroy_Cuda(CeedBasis basis) { Ceed ceed; CeedBasis_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedBasisGetData(basis, &data)); CeedCallCuda(ceed, cuModuleUnload(data->module)); if (data->moduleAtPoints) CeedCallCuda(ceed, cuModuleUnload(data->moduleAtPoints)); if (data->d_q_weight_1d) CeedCallCuda(ceed, cudaFree(data->d_q_weight_1d)); CeedCallBackend(CeedFree(&data->h_points_per_elem)); if (data->d_points_per_elem) CeedCallCuda(ceed, cudaFree(data->d_points_per_elem)); CeedCallCuda(ceed, cudaFree(data->d_interp_1d)); CeedCallCuda(ceed, cudaFree(data->d_grad_1d)); CeedCallCuda(ceed, cudaFree(data->d_chebyshev_interp_1d)); CeedCallBackend(CeedFree(&data)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Destroy non-tensor basis //------------------------------------------------------------------------------ static int CeedBasisDestroyNonTensor_Cuda(CeedBasis basis) { Ceed ceed; CeedBasisNonTensor_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedBasisGetData(basis, &data)); CeedCallCuda(ceed, cuModuleUnload(data->module)); if (data->d_q_weight) CeedCallCuda(ceed, cudaFree(data->d_q_weight)); CeedCallCuda(ceed, cudaFree(data->d_interp)); CeedCallCuda(ceed, cudaFree(data->d_grad)); CeedCallCuda(ceed, cudaFree(data->d_div)); CeedCallCuda(ceed, cudaFree(data->d_curl)); CeedCallBackend(CeedFree(&data)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Create tensor //------------------------------------------------------------------------------ int CeedBasisCreateTensorH1_Cuda(CeedInt dim, CeedInt P_1d, CeedInt Q_1d, const CeedScalar *interp_1d, const CeedScalar *grad_1d, const CeedScalar *q_ref_1d, const CeedScalar *q_weight_1d, CeedBasis basis) { Ceed ceed; CeedInt num_comp; const CeedInt q_bytes = Q_1d * sizeof(CeedScalar); const CeedInt interp_bytes = q_bytes * P_1d; CeedBasis_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedCalloc(1, &data)); // Copy data to GPU if (q_weight_1d) { CeedCallCuda(ceed, cudaMalloc((void **)&data->d_q_weight_1d, q_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_q_weight_1d, q_weight_1d, q_bytes, cudaMemcpyHostToDevice)); } CeedCallCuda(ceed, cudaMalloc((void **)&data->d_interp_1d, interp_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_interp_1d, interp_1d, interp_bytes, cudaMemcpyHostToDevice)); CeedCallCuda(ceed, cudaMalloc((void **)&data->d_grad_1d, interp_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_grad_1d, grad_1d, interp_bytes, cudaMemcpyHostToDevice)); // Compile basis kernels const char basis_kernel_source[] = "// Tensor basis source\n#include \n"; CeedCallBackend(CeedBasisGetNumComponents(basis, &num_comp)); CeedCallBackend(CeedCompile_Cuda(ceed, basis_kernel_source, &data->module, 7, "BASIS_Q_1D", Q_1d, "BASIS_P_1D", P_1d, "BASIS_BUF_LEN", Q_1d * CeedIntPow(Q_1d > P_1d ? Q_1d : P_1d, dim - 1), "BASIS_DIM", dim, "BASIS_NUM_COMP", num_comp, "BASIS_NUM_NODES", CeedIntPow(P_1d, dim), "BASIS_NUM_QPTS", CeedIntPow(Q_1d, dim))); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Interp", &data->Interp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Grad", &data->Grad)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Weight", &data->Weight)); CeedCallBackend(CeedBasisSetData(basis, data)); // Register backend functions CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApply_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "ApplyAdd", CeedBasisApplyAdd_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "ApplyAtPoints", CeedBasisApplyAtPoints_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "ApplyAddAtPoints", CeedBasisApplyAddAtPoints_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Destroy", CeedBasisDestroy_Cuda)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Create non-tensor H^1 //------------------------------------------------------------------------------ int CeedBasisCreateH1_Cuda(CeedElemTopology topo, CeedInt dim, CeedInt num_nodes, CeedInt num_qpts, const CeedScalar *interp, const CeedScalar *grad, const CeedScalar *q_ref, const CeedScalar *q_weight, CeedBasis basis) { Ceed ceed; CeedInt num_comp, q_comp_interp, q_comp_grad; const CeedInt q_bytes = num_qpts * sizeof(CeedScalar); CeedBasisNonTensor_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedCalloc(1, &data)); // Copy basis data to GPU CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, CEED_EVAL_INTERP, &q_comp_interp)); CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, CEED_EVAL_GRAD, &q_comp_grad)); if (q_weight) { CeedCallCuda(ceed, cudaMalloc((void **)&data->d_q_weight, q_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_q_weight, q_weight, q_bytes, cudaMemcpyHostToDevice)); } if (interp) { const CeedInt interp_bytes = q_bytes * num_nodes * q_comp_interp; CeedCallCuda(ceed, cudaMalloc((void **)&data->d_interp, interp_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_interp, interp, interp_bytes, cudaMemcpyHostToDevice)); } if (grad) { const CeedInt grad_bytes = q_bytes * num_nodes * q_comp_grad; CeedCallCuda(ceed, cudaMalloc((void **)&data->d_grad, grad_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_grad, grad, grad_bytes, cudaMemcpyHostToDevice)); } // Compile basis kernels const char basis_kernel_source[] = "// Nontensor basis source\n#include \n"; CeedCallBackend(CeedBasisGetNumComponents(basis, &num_comp)); CeedCallBackend(CeedCompile_Cuda(ceed, basis_kernel_source, &data->module, 5, "BASIS_Q", num_qpts, "BASIS_P", num_nodes, "BASIS_Q_COMP_INTERP", q_comp_interp, "BASIS_Q_COMP_DERIV", q_comp_grad, "BASIS_NUM_COMP", num_comp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Interp", &data->Interp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "InterpTranspose", &data->InterpTranspose)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Deriv", &data->Deriv)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "DerivTranspose", &data->DerivTranspose)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Weight", &data->Weight)); CeedCallBackend(CeedBasisSetData(basis, data)); // Register backend functions CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApplyNonTensor_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "ApplyAdd", CeedBasisApplyAddNonTensor_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Destroy", CeedBasisDestroyNonTensor_Cuda)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Create non-tensor H(div) //------------------------------------------------------------------------------ int CeedBasisCreateHdiv_Cuda(CeedElemTopology topo, CeedInt dim, CeedInt num_nodes, CeedInt num_qpts, const CeedScalar *interp, const CeedScalar *div, const CeedScalar *q_ref, const CeedScalar *q_weight, CeedBasis basis) { Ceed ceed; CeedInt num_comp, q_comp_interp, q_comp_div; const CeedInt q_bytes = num_qpts * sizeof(CeedScalar); CeedBasisNonTensor_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedCalloc(1, &data)); // Copy basis data to GPU CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, CEED_EVAL_INTERP, &q_comp_interp)); CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, CEED_EVAL_DIV, &q_comp_div)); if (q_weight) { CeedCallCuda(ceed, cudaMalloc((void **)&data->d_q_weight, q_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_q_weight, q_weight, q_bytes, cudaMemcpyHostToDevice)); } if (interp) { const CeedInt interp_bytes = q_bytes * num_nodes * q_comp_interp; CeedCallCuda(ceed, cudaMalloc((void **)&data->d_interp, interp_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_interp, interp, interp_bytes, cudaMemcpyHostToDevice)); } if (div) { const CeedInt div_bytes = q_bytes * num_nodes * q_comp_div; CeedCallCuda(ceed, cudaMalloc((void **)&data->d_div, div_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_div, div, div_bytes, cudaMemcpyHostToDevice)); } // Compile basis kernels const char basis_kernel_source[] = "// Nontensor basis source\n#include \n"; CeedCallBackend(CeedBasisGetNumComponents(basis, &num_comp)); CeedCallBackend(CeedCompile_Cuda(ceed, basis_kernel_source, &data->module, 5, "BASIS_Q", num_qpts, "BASIS_P", num_nodes, "BASIS_Q_COMP_INTERP", q_comp_interp, "BASIS_Q_COMP_DERIV", q_comp_div, "BASIS_NUM_COMP", num_comp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Interp", &data->Interp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "InterpTranspose", &data->InterpTranspose)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Deriv", &data->Deriv)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "DerivTranspose", &data->DerivTranspose)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Weight", &data->Weight)); CeedCallBackend(CeedBasisSetData(basis, data)); // Register backend functions CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApplyNonTensor_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "ApplyAdd", CeedBasisApplyAddNonTensor_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Destroy", CeedBasisDestroyNonTensor_Cuda)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Create non-tensor H(curl) //------------------------------------------------------------------------------ int CeedBasisCreateHcurl_Cuda(CeedElemTopology topo, CeedInt dim, CeedInt num_nodes, CeedInt num_qpts, const CeedScalar *interp, const CeedScalar *curl, const CeedScalar *q_ref, const CeedScalar *q_weight, CeedBasis basis) { Ceed ceed; CeedInt num_comp, q_comp_interp, q_comp_curl; const CeedInt q_bytes = num_qpts * sizeof(CeedScalar); CeedBasisNonTensor_Cuda *data; CeedCallBackend(CeedBasisGetCeed(basis, &ceed)); CeedCallBackend(CeedCalloc(1, &data)); // Copy basis data to GPU CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, CEED_EVAL_INTERP, &q_comp_interp)); CeedCallBackend(CeedBasisGetNumQuadratureComponents(basis, CEED_EVAL_CURL, &q_comp_curl)); if (q_weight) { CeedCallCuda(ceed, cudaMalloc((void **)&data->d_q_weight, q_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_q_weight, q_weight, q_bytes, cudaMemcpyHostToDevice)); } if (interp) { const CeedInt interp_bytes = q_bytes * num_nodes * q_comp_interp; CeedCallCuda(ceed, cudaMalloc((void **)&data->d_interp, interp_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_interp, interp, interp_bytes, cudaMemcpyHostToDevice)); } if (curl) { const CeedInt curl_bytes = q_bytes * num_nodes * q_comp_curl; CeedCallCuda(ceed, cudaMalloc((void **)&data->d_curl, curl_bytes)); CeedCallCuda(ceed, cudaMemcpy(data->d_curl, curl, curl_bytes, cudaMemcpyHostToDevice)); } // Compile basis kernels const char basis_kernel_source[] = "// Nontensor basis source\n#include \n"; CeedCallBackend(CeedBasisGetNumComponents(basis, &num_comp)); CeedCallBackend(CeedCompile_Cuda(ceed, basis_kernel_source, &data->module, 5, "BASIS_Q", num_qpts, "BASIS_P", num_nodes, "BASIS_Q_COMP_INTERP", q_comp_interp, "BASIS_Q_COMP_DERIV", q_comp_curl, "BASIS_NUM_COMP", num_comp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Interp", &data->Interp)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "InterpTranspose", &data->InterpTranspose)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Deriv", &data->Deriv)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "DerivTranspose", &data->DerivTranspose)); CeedCallBackend(CeedGetKernel_Cuda(ceed, data->module, "Weight", &data->Weight)); CeedCallBackend(CeedBasisSetData(basis, data)); // Register backend functions CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApplyNonTensor_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "ApplyAdd", CeedBasisApplyAddNonTensor_Cuda)); CeedCallBackend(CeedSetBackendFunction(ceed, "Basis", basis, "Destroy", CeedBasisDestroyNonTensor_Cuda)); CeedCallBackend(CeedDestroy(&ceed)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------