// Copyright (c) 2017-2022, 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 "../sycl/ceed-sycl-compile.hpp" #include "ceed-sycl-ref.hpp" class CeedOperatorSyclLinearDiagonal; class CeedOperatorSyclLinearAssemble; class CeedOperatorSyclLinearAssembleFallback; //------------------------------------------------------------------------------ // Get Basis Emode Pointer //------------------------------------------------------------------------------ void CeedOperatorGetBasisPointer_Sycl(const CeedScalar **basis_ptr, CeedEvalMode e_mode, const CeedScalar *identity, const CeedScalar *interp, const CeedScalar *grad) { switch (e_mode) { case CEED_EVAL_NONE: *basis_ptr = identity; break; case CEED_EVAL_INTERP: *basis_ptr = interp; break; case CEED_EVAL_GRAD: *basis_ptr = grad; break; case CEED_EVAL_WEIGHT: case CEED_EVAL_DIV: case CEED_EVAL_CURL: break; // Caught by QF Assembly } } //------------------------------------------------------------------------------ // Destroy operator //------------------------------------------------------------------------------ static int CeedOperatorDestroy_Sycl(CeedOperator op) { Ceed ceed; Ceed_Sycl *sycl_data; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedGetData(ceed, &sycl_data)); // Apply data for (CeedInt i = 0; i < impl->num_e_in + impl->num_e_out; i++) { CeedCallBackend(CeedVectorDestroy(&impl->e_vecs[i])); } CeedCallBackend(CeedFree(&impl->e_vecs)); for (CeedInt i = 0; i < impl->num_e_in; i++) { CeedCallBackend(CeedVectorDestroy(&impl->q_vecs_in[i])); } CeedCallBackend(CeedFree(&impl->q_vecs_in)); for (CeedInt i = 0; i < impl->num_e_out; i++) { CeedCallBackend(CeedVectorDestroy(&impl->q_vecs_out[i])); } CeedCallBackend(CeedFree(&impl->q_vecs_out)); // QFunction assembly data for (CeedInt i = 0; i < impl->num_active_in; i++) { CeedCallBackend(CeedVectorDestroy(&impl->qf_active_in[i])); } CeedCallBackend(CeedFree(&impl->qf_active_in)); // Diag data if (impl->diag) { CeedCallBackend(CeedFree(&impl->diag->h_e_mode_in)); CeedCallBackend(CeedFree(&impl->diag->h_e_mode_out)); CeedCallSycl(ceed, sycl_data->sycl_queue.wait_and_throw()); CeedCallSycl(ceed, sycl::free(impl->diag->d_e_mode_in, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->diag->d_e_mode_out, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->diag->d_identity, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->diag->d_interp_in, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->diag->d_interp_out, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->diag->d_grad_in, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->diag->d_grad_out, sycl_data->sycl_context)); CeedCallBackend(CeedElemRestrictionDestroy(&impl->diag->point_block_diag_rstr)); CeedCallBackend(CeedVectorDestroy(&impl->diag->elem_diag)); CeedCallBackend(CeedVectorDestroy(&impl->diag->point_block_elem_diag)); } CeedCallBackend(CeedFree(&impl->diag)); if (impl->asmb) { CeedCallSycl(ceed, sycl_data->sycl_queue.wait_and_throw()); CeedCallSycl(ceed, sycl::free(impl->asmb->d_B_in, sycl_data->sycl_context)); CeedCallSycl(ceed, sycl::free(impl->asmb->d_B_out, sycl_data->sycl_context)); } CeedCallBackend(CeedFree(&impl->asmb)); CeedCallBackend(CeedFree(&impl)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Setup infields or outfields //------------------------------------------------------------------------------ static int CeedOperatorSetupFields_Sycl(CeedQFunction qf, CeedOperator op, bool is_input, CeedVector *e_vecs, CeedVector *q_vecs, CeedInt start_e, CeedInt num_fields, CeedInt Q, CeedInt num_elem) { Ceed ceed; CeedSize q_size; bool is_strided, skip_restriction; CeedInt dim, size; CeedOperatorField *op_fields; CeedQFunctionField *qf_fields; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); if (is_input) { CeedCallBackend(CeedOperatorGetFields(op, NULL, &op_fields, NULL, NULL)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_fields, NULL, NULL)); } else { CeedCallBackend(CeedOperatorGetFields(op, NULL, NULL, NULL, &op_fields)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, NULL, NULL, &qf_fields)); } // Loop over fields for (CeedInt i = 0; i < num_fields; i++) { CeedEvalMode e_mode; CeedVector vec; CeedElemRestriction rstr; CeedBasis basis; CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &e_mode)); is_strided = false; skip_restriction = false; if (e_mode != CEED_EVAL_WEIGHT) { CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_fields[i], &rstr)); // Check whether this field can skip the element restriction: // must be passive input, with e_mode NONE, and have a strided restriction with CEED_STRIDES_BACKEND. // First, check whether the field is input or output: if (is_input) { // Check for passive input: CeedCallBackend(CeedOperatorFieldGetVector(op_fields[i], &vec)); if (vec != CEED_VECTOR_ACTIVE) { // Check e_mode if (e_mode == CEED_EVAL_NONE) { // Check for is_strided restriction CeedCallBackend(CeedElemRestrictionIsStrided(rstr, &is_strided)); if (is_strided) { // Check if vector is already in preferred backend ordering CeedCallBackend(CeedElemRestrictionHasBackendStrides(rstr, &skip_restriction)); } } } } if (skip_restriction) { // We do not need an E-Vector, but will use the input field vector's data directly in the operator application e_vecs[i + start_e] = NULL; } else { CeedCallBackend(CeedElemRestrictionCreateVector(rstr, NULL, &e_vecs[i + start_e])); } } switch (e_mode) { case CEED_EVAL_NONE: CeedCallBackend(CeedQFunctionFieldGetSize(qf_fields[i], &size)); q_size = (CeedSize)num_elem * Q * size; CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i])); break; case CEED_EVAL_INTERP: CeedCallBackend(CeedQFunctionFieldGetSize(qf_fields[i], &size)); q_size = (CeedSize)num_elem * Q * size; CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i])); break; case CEED_EVAL_GRAD: CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis)); CeedCallBackend(CeedQFunctionFieldGetSize(qf_fields[i], &size)); CeedCallBackend(CeedBasisGetDimension(basis, &dim)); q_size = (CeedSize)num_elem * Q * size; CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i])); break; case CEED_EVAL_WEIGHT: // Only on input fields CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis)); q_size = (CeedSize)num_elem * Q; CeedCallBackend(CeedVectorCreate(ceed, q_size, &q_vecs[i])); CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_NOTRANSPOSE, CEED_EVAL_WEIGHT, NULL, q_vecs[i])); break; case CEED_EVAL_DIV: break; // TODO: Not implemented case CEED_EVAL_CURL: break; // TODO: Not implemented } } return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // CeedOperator needs to connect all the named fields (be they active or // passive) to the named inputs and outputs of its CeedQFunction. //------------------------------------------------------------------------------ static int CeedOperatorSetup_Sycl(CeedOperator op) { Ceed ceed; bool is_setup_done; CeedInt Q, num_elem, num_input_fields, num_output_fields; CeedQFunctionField *qf_input_fields, *qf_output_fields; CeedQFunction qf; CeedOperatorField *op_input_fields, *op_output_fields; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorIsSetupDone(op, &is_setup_done)); if (is_setup_done) return CEED_ERROR_SUCCESS; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedOperatorGetQFunction(op, &qf)); CeedCallBackend(CeedOperatorGetNumQuadraturePoints(op, &Q)); CeedCallBackend(CeedOperatorGetNumElements(op, &num_elem)); CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &op_input_fields, &num_output_fields, &op_output_fields)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_input_fields, NULL, &qf_output_fields)); // Allocate CeedCallBackend(CeedCalloc(num_input_fields + num_output_fields, &impl->e_vecs)); CeedCallBackend(CeedCalloc(CEED_FIELD_MAX, &impl->q_vecs_in)); CeedCallBackend(CeedCalloc(CEED_FIELD_MAX, &impl->q_vecs_out)); impl->num_e_in = num_input_fields; impl->num_e_out = num_output_fields; // Set up infield and outfield e_vecs and q_vecs // Infields CeedCallBackend(CeedOperatorSetupFields_Sycl(qf, op, true, impl->e_vecs, impl->q_vecs_in, 0, num_input_fields, Q, num_elem)); // Outfields CeedCallBackend(CeedOperatorSetupFields_Sycl(qf, op, false, impl->e_vecs, impl->q_vecs_out, num_input_fields, num_output_fields, Q, num_elem)); CeedCallBackend(CeedOperatorSetSetupDone(op)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Setup Operator Inputs //------------------------------------------------------------------------------ static inline int CeedOperatorSetupInputs_Sycl(CeedInt num_input_fields, CeedQFunctionField *qf_input_fields, CeedOperatorField *op_input_fields, CeedVector in_vec, const bool skip_active, CeedScalar *e_data[2 * CEED_FIELD_MAX], CeedOperator_Sycl *impl, CeedRequest *request) { for (CeedInt i = 0; i < num_input_fields; i++) { CeedEvalMode e_mode; CeedVector vec; CeedElemRestriction rstr; // Get input vector CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) { if (skip_active) continue; else vec = in_vec; } CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_input_fields[i], &e_mode)); if (e_mode == CEED_EVAL_WEIGHT) { // Skip } else { // Get input vector CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec)); // Get input element restriction CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_input_fields[i], &rstr)); if (vec == CEED_VECTOR_ACTIVE) vec = in_vec; // Restrict, if necessary if (!impl->e_vecs[i]) { // No restriction for this field; read data directly from vec. CeedCallBackend(CeedVectorGetArrayRead(vec, CEED_MEM_DEVICE, (const CeedScalar **)&e_data[i])); } else { CeedCallBackend(CeedElemRestrictionApply(rstr, CEED_NOTRANSPOSE, vec, impl->e_vecs[i], request)); // Get evec CeedCallBackend(CeedVectorGetArrayRead(impl->e_vecs[i], CEED_MEM_DEVICE, (const CeedScalar **)&e_data[i])); } } } return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Input Basis Action //------------------------------------------------------------------------------ static inline int CeedOperatorInputBasis_Sycl(CeedInt num_elem, CeedQFunctionField *qf_input_fields, CeedOperatorField *op_input_fields, CeedInt num_input_fields, const bool skip_active, CeedScalar *e_data[2 * CEED_FIELD_MAX], CeedOperator_Sycl *impl) { for (CeedInt i = 0; i < num_input_fields; i++) { CeedInt elem_size, size; CeedElemRestriction rstr; CeedEvalMode e_mode; CeedBasis basis; // Skip active input if (skip_active) { CeedVector vec; CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) continue; } // Get elem_size, e_mode, size CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_input_fields[i], &rstr)); CeedCallBackend(CeedElemRestrictionGetElementSize(rstr, &elem_size)); CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_input_fields[i], &e_mode)); CeedCallBackend(CeedQFunctionFieldGetSize(qf_input_fields[i], &size)); // Basis action switch (e_mode) { case CEED_EVAL_NONE: CeedCallBackend(CeedVectorSetArray(impl->q_vecs_in[i], CEED_MEM_DEVICE, CEED_USE_POINTER, e_data[i])); break; case CEED_EVAL_INTERP: CeedCallBackend(CeedOperatorFieldGetBasis(op_input_fields[i], &basis)); CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_NOTRANSPOSE, CEED_EVAL_INTERP, impl->e_vecs[i], impl->q_vecs_in[i])); break; case CEED_EVAL_GRAD: CeedCallBackend(CeedOperatorFieldGetBasis(op_input_fields[i], &basis)); CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_NOTRANSPOSE, CEED_EVAL_GRAD, impl->e_vecs[i], impl->q_vecs_in[i])); break; case CEED_EVAL_WEIGHT: break; // No action case CEED_EVAL_DIV: break; // TODO: Not implemented case CEED_EVAL_CURL: break; // TODO: Not implemented } } return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Restore Input Vectors //------------------------------------------------------------------------------ static inline int CeedOperatorRestoreInputs_Sycl(CeedInt num_input_fields, CeedQFunctionField *qf_input_fields, CeedOperatorField *op_input_fields, const bool skip_active, CeedScalar *e_data[2 * CEED_FIELD_MAX], CeedOperator_Sycl *impl) { for (CeedInt i = 0; i < num_input_fields; i++) { CeedEvalMode e_mode; CeedVector vec; // Skip active input if (skip_active) { CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) continue; } CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_input_fields[i], &e_mode)); if (e_mode == CEED_EVAL_WEIGHT) { // Skip } else { if (!impl->e_vecs[i]) { // This was a skip_restriction case CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec)); CeedCallBackend(CeedVectorRestoreArrayRead(vec, (const CeedScalar **)&e_data[i])); } else { CeedCallBackend(CeedVectorRestoreArrayRead(impl->e_vecs[i], (const CeedScalar **)&e_data[i])); } } } return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Apply and add to output //------------------------------------------------------------------------------ static int CeedOperatorApplyAdd_Sycl(CeedOperator op, CeedVector in_vec, CeedVector out_vec, CeedRequest *request) { CeedInt Q, num_elem, elem_size, num_input_fields, num_output_fields, size; CeedEvalMode e_mode; CeedScalar *e_data[2 * CEED_FIELD_MAX] = {0}; CeedQFunctionField *qf_input_fields, *qf_output_fields; CeedQFunction qf; CeedOperatorField *op_input_fields, *op_output_fields; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedOperatorGetQFunction(op, &qf)); CeedCallBackend(CeedOperatorGetNumQuadraturePoints(op, &Q)); CeedCallBackend(CeedOperatorGetNumElements(op, &num_elem)); CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &op_input_fields, &num_output_fields, &op_output_fields)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_input_fields, NULL, &qf_output_fields)); // Setup CeedCallBackend(CeedOperatorSetup_Sycl(op)); // Input Evecs and Restriction CeedCallBackend(CeedOperatorSetupInputs_Sycl(num_input_fields, qf_input_fields, op_input_fields, in_vec, false, e_data, impl, request)); // Input basis apply if needed CeedCallBackend(CeedOperatorInputBasis_Sycl(num_elem, qf_input_fields, op_input_fields, num_input_fields, false, e_data, impl)); // Output pointers, as necessary for (CeedInt i = 0; i < num_output_fields; i++) { CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_output_fields[i], &e_mode)); if (e_mode == CEED_EVAL_NONE) { // Set the output Q-Vector to use the E-Vector data directly CeedCallBackend(CeedVectorGetArrayWrite(impl->e_vecs[i + impl->num_e_in], CEED_MEM_DEVICE, &e_data[i + num_input_fields])); CeedCallBackend(CeedVectorSetArray(impl->q_vecs_out[i], CEED_MEM_DEVICE, CEED_USE_POINTER, e_data[i + num_input_fields])); } } // Q function CeedCallBackend(CeedQFunctionApply(qf, num_elem * Q, impl->q_vecs_in, impl->q_vecs_out)); // Output basis apply if needed for (CeedInt i = 0; i < num_output_fields; i++) { CeedElemRestriction rstr; CeedBasis basis; // Get elem_size, e_mode, size CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_output_fields[i], &rstr)); CeedCallBackend(CeedElemRestrictionGetElementSize(rstr, &elem_size)); CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_output_fields[i], &e_mode)); CeedCallBackend(CeedQFunctionFieldGetSize(qf_output_fields[i], &size)); // Basis action switch (e_mode) { case CEED_EVAL_NONE: break; case CEED_EVAL_INTERP: CeedCallBackend(CeedOperatorFieldGetBasis(op_output_fields[i], &basis)); CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_TRANSPOSE, CEED_EVAL_INTERP, impl->q_vecs_out[i], impl->e_vecs[i + impl->num_e_in])); break; case CEED_EVAL_GRAD: CeedCallBackend(CeedOperatorFieldGetBasis(op_output_fields[i], &basis)); CeedCallBackend(CeedBasisApply(basis, num_elem, CEED_TRANSPOSE, CEED_EVAL_GRAD, impl->q_vecs_out[i], impl->e_vecs[i + impl->num_e_in])); break; // LCOV_EXCL_START case CEED_EVAL_WEIGHT: Ceed ceed; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_WEIGHT cannot be an output evaluation mode"); break; // Should not occur case CEED_EVAL_DIV: break; // TODO: Not implemented case CEED_EVAL_CURL: break; // TODO: Not implemented // LCOV_EXCL_STOP } } // Output restriction for (CeedInt i = 0; i < num_output_fields; i++) { CeedVector vec; CeedElemRestriction rstr; // Restore evec CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_output_fields[i], &e_mode)); if (e_mode == CEED_EVAL_NONE) { CeedCallBackend(CeedVectorRestoreArray(impl->e_vecs[i + impl->num_e_in], &e_data[i + num_input_fields])); } // Get output vector CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[i], &vec)); // Restrict CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_output_fields[i], &rstr)); // Active if (vec == CEED_VECTOR_ACTIVE) vec = out_vec; CeedCallBackend(CeedElemRestrictionApply(rstr, CEED_TRANSPOSE, impl->e_vecs[i + impl->num_e_in], vec, request)); } // Restore input arrays CeedCallBackend(CeedOperatorRestoreInputs_Sycl(num_input_fields, qf_input_fields, op_input_fields, false, e_data, impl)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Core code for assembling linear QFunction //------------------------------------------------------------------------------ static inline int CeedOperatorLinearAssembleQFunctionCore_Sycl(CeedOperator op, bool build_objects, CeedVector *assembled, CeedElemRestriction *rstr, CeedRequest *request) { Ceed ceed, ceed_parent; CeedSize q_size; CeedInt num_active_in, num_active_out, Q, num_elem, num_input_fields, num_output_fields, size; CeedScalar *assembled_array, *e_data[2 * CEED_FIELD_MAX] = {NULL}; CeedVector *active_in; CeedQFunctionField *qf_input_fields, *qf_output_fields; CeedQFunction qf; CeedOperatorField *op_input_fields, *op_output_fields; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedOperatorGetFallbackParentCeed(op, &ceed_parent)); CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedOperatorGetQFunction(op, &qf)); CeedCallBackend(CeedOperatorGetNumQuadraturePoints(op, &Q)); CeedCallBackend(CeedOperatorGetNumElements(op, &num_elem)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_input_fields, NULL, &qf_output_fields)); CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &op_input_fields, &num_output_fields, &op_output_fields)); active_in = impl->qf_active_in; num_active_in = impl->num_active_in, num_active_out = impl->num_active_out; // Setup CeedCallBackend(CeedOperatorSetup_Sycl(op)); // Check for identity bool is_identity_qf; CeedCallBackend(CeedQFunctionIsIdentity(qf, &is_identity_qf)); if (is_identity_qf) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "Assembling identity QFunctions not supported"); // LCOV_EXCL_STOP } // Input Evecs and Restriction CeedCallBackend(CeedOperatorSetupInputs_Sycl(num_input_fields, qf_input_fields, op_input_fields, NULL, true, e_data, impl, request)); // Count number of active input fields if (!num_active_in) { for (CeedInt i = 0; i < num_input_fields; i++) { CeedScalar *q_vec_array; CeedVector vec; // Get input vector CeedCallBackend(CeedOperatorFieldGetVector(op_input_fields[i], &vec)); // Check if active input if (vec == CEED_VECTOR_ACTIVE) { CeedCallBackend(CeedQFunctionFieldGetSize(qf_input_fields[i], &size)); CeedCallBackend(CeedVectorSetValue(impl->q_vecs_in[i], 0.0)); CeedCallBackend(CeedVectorGetArray(impl->q_vecs_in[i], CEED_MEM_DEVICE, &q_vec_array)); CeedCallBackend(CeedRealloc(num_active_in + size, &active_in)); for (CeedInt field = 0; field < size; field++) { q_size = (CeedSize)Q * num_elem; CeedCallBackend(CeedVectorCreate(ceed, q_size, &active_in[num_active_in + field])); CeedCallBackend( CeedVectorSetArray(active_in[num_active_in + field], CEED_MEM_DEVICE, CEED_USE_POINTER, &q_vec_array[field * Q * num_elem])); } num_active_in += size; CeedCallBackend(CeedVectorRestoreArray(impl->q_vecs_in[i], &q_vec_array)); } } impl->num_active_in = num_active_in; impl->qf_active_in = active_in; } // Count number of active output fields if (!num_active_out) { for (CeedInt i = 0; i < num_output_fields; i++) { CeedVector vec; // Get output vector CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[i], &vec)); // Check if active output if (vec == CEED_VECTOR_ACTIVE) { CeedCallBackend(CeedQFunctionFieldGetSize(qf_output_fields[i], &size)); num_active_out += size; } } impl->num_active_out = num_active_out; } // Check sizes if (!num_active_in || !num_active_out) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "Cannot assemble QFunction without active inputs and outputs"); // LCOV_EXCL_STOP } // Build objects if needed if (build_objects) { CeedSize l_size = (CeedSize)num_elem * Q * num_active_in * num_active_out; CeedInt strides[3] = {1, num_elem * Q, Q}; /* *NOPAD* */ // Create output restriction CeedCallBackend(CeedElemRestrictionCreateStrided(ceed_parent, num_elem, Q, num_active_in * num_active_out, num_active_in * num_active_out * num_elem * Q, strides, rstr)); // Create assembled vector CeedCallBackend(CeedVectorCreate(ceed_parent, l_size, assembled)); } CeedCallBackend(CeedVectorSetValue(*assembled, 0.0)); CeedCallBackend(CeedVectorGetArray(*assembled, CEED_MEM_DEVICE, &assembled_array)); // Input basis apply CeedCallBackend(CeedOperatorInputBasis_Sycl(num_elem, qf_input_fields, op_input_fields, num_input_fields, true, e_data, impl)); // Assemble QFunction for (CeedInt in = 0; in < num_active_in; in++) { // Set Inputs CeedCallBackend(CeedVectorSetValue(active_in[in], 1.0)); if (num_active_in > 1) { CeedCallBackend(CeedVectorSetValue(active_in[(in + num_active_in - 1) % num_active_in], 0.0)); } // Set Outputs for (CeedInt out = 0; out < num_output_fields; out++) { CeedVector vec; // Get output vector CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[out], &vec)); // Check if active output if (vec == CEED_VECTOR_ACTIVE) { CeedCallBackend(CeedVectorSetArray(impl->q_vecs_out[out], CEED_MEM_DEVICE, CEED_USE_POINTER, assembled_array)); CeedCallBackend(CeedQFunctionFieldGetSize(qf_output_fields[out], &size)); assembled_array += size * Q * num_elem; // Advance the pointer by the size of the output } } // Apply QFunction CeedCallBackend(CeedQFunctionApply(qf, Q * num_elem, impl->q_vecs_in, impl->q_vecs_out)); } // Un-set output Qvecs to prevent accidental overwrite of Assembled for (CeedInt out = 0; out < num_output_fields; out++) { CeedVector vec; // Get output vector CeedCallBackend(CeedOperatorFieldGetVector(op_output_fields[out], &vec)); // Check if active output if (vec == CEED_VECTOR_ACTIVE) { CeedCallBackend(CeedVectorTakeArray(impl->q_vecs_out[out], CEED_MEM_DEVICE, NULL)); } } // Restore input arrays CeedCallBackend(CeedOperatorRestoreInputs_Sycl(num_input_fields, qf_input_fields, op_input_fields, true, e_data, impl)); // Restore output CeedCallBackend(CeedVectorRestoreArray(*assembled, &assembled_array)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Assemble Linear QFunction //------------------------------------------------------------------------------ static int CeedOperatorLinearAssembleQFunction_Sycl(CeedOperator op, CeedVector *assembled, CeedElemRestriction *rstr, CeedRequest *request) { return CeedOperatorLinearAssembleQFunctionCore_Sycl(op, true, assembled, rstr, request); } //------------------------------------------------------------------------------ // Update Assembled Linear QFunction //------------------------------------------------------------------------------ static int CeedOperatorLinearAssembleQFunctionUpdate_Sycl(CeedOperator op, CeedVector assembled, CeedElemRestriction rstr, CeedRequest *request) { return CeedOperatorLinearAssembleQFunctionCore_Sycl(op, false, &assembled, &rstr, request); } //------------------------------------------------------------------------------ // Create point block restriction //------------------------------------------------------------------------------ static int CreatePBRestriction(CeedElemRestriction rstr, CeedElemRestriction *point_block_rstr) { Ceed ceed; CeedSize l_size; CeedInt num_elem, num_comp, elem_size, comp_stride, *point_block_offsets; const CeedInt *offsets; CeedCallBackend(CeedElemRestrictionGetCeed(rstr, &ceed)); CeedCallBackend(CeedElemRestrictionGetOffsets(rstr, CEED_MEM_HOST, &offsets)); // Expand offsets CeedCallBackend(CeedElemRestrictionGetNumElements(rstr, &num_elem)); CeedCallBackend(CeedElemRestrictionGetNumComponents(rstr, &num_comp)); CeedCallBackend(CeedElemRestrictionGetElementSize(rstr, &elem_size)); CeedCallBackend(CeedElemRestrictionGetCompStride(rstr, &comp_stride)); CeedCallBackend(CeedElemRestrictionGetLVectorSize(rstr, &l_size)); CeedInt shift = num_comp; if (comp_stride != 1) shift *= num_comp; CeedCallBackend(CeedCalloc(num_elem * elem_size, &point_block_offsets)); for (CeedInt i = 0; i < num_elem * elem_size; i++) { point_block_offsets[i] = offsets[i] * shift; } // Create new restriction CeedCallBackend(CeedElemRestrictionCreate(ceed, num_elem, elem_size, num_comp * num_comp, 1, l_size * num_comp, CEED_MEM_HOST, CEED_OWN_POINTER, point_block_offsets, point_block_rstr)); // Cleanup CeedCallBackend(CeedElemRestrictionRestoreOffsets(rstr, &offsets)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Assemble diagonal setup //------------------------------------------------------------------------------ static inline int CeedOperatorAssembleDiagonalSetup_Sycl(CeedOperator op, const bool is_point_block) { Ceed ceed; Ceed_Sycl *sycl_data; CeedInt num_input_fields, num_output_fields, num_e_mode_in = 0, num_comp = 0, dim = 1, num_e_mode_out = 0; CeedEvalMode *e_mode_in = NULL, *e_mode_out = NULL; CeedBasis basis_in = NULL, basis_out = NULL; CeedElemRestriction rstr_in = NULL, rstr_out = NULL; CeedQFunctionField *qf_fields; CeedQFunction qf; CeedOperatorField *op_fields; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedOperatorGetQFunction(op, &qf)); CeedCallBackend(CeedQFunctionGetNumArgs(qf, &num_input_fields, &num_output_fields)); // Determine active input basis CeedCallBackend(CeedOperatorGetFields(op, NULL, &op_fields, NULL, NULL)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_fields, NULL, NULL)); for (CeedInt i = 0; i < num_input_fields; i++) { CeedVector vec; CeedCallBackend(CeedOperatorFieldGetVector(op_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) { CeedEvalMode e_mode; CeedElemRestriction rstr; CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis_in)); CeedCallBackend(CeedBasisGetNumComponents(basis_in, &num_comp)); CeedCallBackend(CeedBasisGetDimension(basis_in, &dim)); CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_fields[i], &rstr)); if (rstr_in && rstr_in != rstr) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "Backend does not implement multi-field non-composite operator diagonal assembly"); // LCOV_EXCL_STOP } rstr_in = rstr; CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &e_mode)); switch (e_mode) { case CEED_EVAL_NONE: case CEED_EVAL_INTERP: CeedCallBackend(CeedRealloc(num_e_mode_in + 1, &e_mode_in)); e_mode_in[num_e_mode_in] = e_mode; num_e_mode_in += 1; break; case CEED_EVAL_GRAD: CeedCallBackend(CeedRealloc(num_e_mode_in + dim, &e_mode_in)); for (CeedInt d = 0; d < dim; d++) e_mode_in[num_e_mode_in + d] = e_mode; num_e_mode_in += dim; break; case CEED_EVAL_WEIGHT: case CEED_EVAL_DIV: case CEED_EVAL_CURL: break; // Caught by QF Assembly } } } // Determine active output basis CeedCallBackend(CeedOperatorGetFields(op, NULL, NULL, NULL, &op_fields)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, NULL, NULL, &qf_fields)); for (CeedInt i = 0; i < num_output_fields; i++) { CeedVector vec; CeedCallBackend(CeedOperatorFieldGetVector(op_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) { CeedEvalMode e_mode; CeedElemRestriction rstr; CeedCallBackend(CeedOperatorFieldGetBasis(op_fields[i], &basis_out)); CeedCallBackend(CeedOperatorFieldGetElemRestriction(op_fields[i], &rstr)); if (rstr_out && rstr_out != rstr) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "Backend does not implement multi-field non-composite operator diagonal assembly"); // LCOV_EXCL_STOP } rstr_out = rstr; CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &e_mode)); switch (e_mode) { case CEED_EVAL_NONE: case CEED_EVAL_INTERP: CeedCallBackend(CeedRealloc(num_e_mode_out + 1, &e_mode_out)); e_mode_out[num_e_mode_out] = e_mode; num_e_mode_out += 1; break; case CEED_EVAL_GRAD: CeedCallBackend(CeedRealloc(num_e_mode_out + dim, &e_mode_out)); for (CeedInt d = 0; d < dim; d++) e_mode_out[num_e_mode_out + d] = e_mode; num_e_mode_out += dim; break; case CEED_EVAL_WEIGHT: case CEED_EVAL_DIV: case CEED_EVAL_CURL: break; // Caught by QF Assembly } } } // Operator data struct CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedGetData(ceed, &sycl_data)); CeedCallBackend(CeedCalloc(1, &impl->diag)); CeedOperatorDiag_Sycl *diag = impl->diag; diag->basis_in = basis_in; diag->basis_out = basis_out; diag->h_e_mode_in = e_mode_in; diag->h_e_mode_out = e_mode_out; diag->num_e_mode_in = num_e_mode_in; diag->num_e_mode_out = num_e_mode_out; // Kernel parameters CeedInt num_nodes, num_qpts; CeedCallBackend(CeedBasisGetNumNodes(basis_in, &num_nodes)); CeedCallBackend(CeedBasisGetNumQuadraturePoints(basis_in, &num_qpts)); diag->num_nodes = num_nodes; diag->num_qpts = num_qpts; diag->num_comp = num_comp; // Basis matrices const CeedInt i_len = num_qpts * num_nodes; const CeedInt g_len = num_qpts * num_nodes * dim; const CeedScalar *interp_in, *interp_out, *grad_in, *grad_out; // CEED_EVAL_NONE CeedScalar *identity = NULL; bool has_eval_none = false; for (CeedInt i = 0; i < num_e_mode_in; i++) has_eval_none = has_eval_none || (e_mode_in[i] == CEED_EVAL_NONE); for (CeedInt i = 0; i < num_e_mode_out; i++) has_eval_none = has_eval_none || (e_mode_out[i] == CEED_EVAL_NONE); // Order queue sycl::event e = sycl_data->sycl_queue.ext_oneapi_submit_barrier(); std::vector copy_events; if (has_eval_none) { CeedCallBackend(CeedCalloc(num_qpts * num_nodes, &identity)); for (CeedSize i = 0; i < (num_nodes < num_qpts ? num_nodes : num_qpts); i++) identity[i * num_nodes + i] = 1.0; CeedCallSycl(ceed, diag->d_identity = sycl::malloc_device(i_len, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event identity_copy = sycl_data->sycl_queue.copy(identity, diag->d_identity, i_len, {e}); copy_events.push_back(identity_copy); } // CEED_EVAL_INTERP CeedCallBackend(CeedBasisGetInterp(basis_in, &interp_in)); CeedCallSycl(ceed, diag->d_interp_in = sycl::malloc_device(i_len, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event interp_in_copy = sycl_data->sycl_queue.copy(interp_in, diag->d_interp_in, i_len, {e}); copy_events.push_back(interp_in_copy); CeedCallBackend(CeedBasisGetInterp(basis_out, &interp_out)); CeedCallSycl(ceed, diag->d_interp_out = sycl::malloc_device(i_len, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event interp_out_copy = sycl_data->sycl_queue.copy(interp_out, diag->d_interp_out, i_len, {e}); copy_events.push_back(interp_out_copy); // CEED_EVAL_GRAD CeedCallBackend(CeedBasisGetGrad(basis_in, &grad_in)); CeedCallSycl(ceed, diag->d_grad_in = sycl::malloc_device(g_len, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event grad_in_copy = sycl_data->sycl_queue.copy(grad_in, diag->d_grad_in, g_len, {e}); copy_events.push_back(grad_in_copy); CeedCallBackend(CeedBasisGetGrad(basis_out, &grad_out)); CeedCallSycl(ceed, diag->d_grad_out = sycl::malloc_device(g_len, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event grad_out_copy = sycl_data->sycl_queue.copy(grad_out, diag->d_grad_out, g_len, {e}); copy_events.push_back(grad_out_copy); // Arrays of e_modes CeedCallSycl(ceed, diag->d_e_mode_in = sycl::malloc_device(num_e_mode_in, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event e_mode_in_copy = sycl_data->sycl_queue.copy(e_mode_in, diag->d_e_mode_in, num_e_mode_in, {e}); copy_events.push_back(e_mode_in_copy); CeedCallSycl(ceed, diag->d_e_mode_out = sycl::malloc_device(num_e_mode_out, sycl_data->sycl_device, sycl_data->sycl_context)); sycl::event e_mode_out_copy = sycl_data->sycl_queue.copy(e_mode_out, diag->d_e_mode_out, num_e_mode_out, {e}); copy_events.push_back(e_mode_out_copy); // Restriction diag->diag_rstr = rstr_out; // Wait for all copies to complete and handle exceptions CeedCallSycl(ceed, sycl::event::wait_and_throw(copy_events)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Kernel for diagonal assembly //------------------------------------------------------------------------------ static int CeedOperatorLinearDiagonal_Sycl(sycl::queue &sycl_queue, const bool is_point_block, const CeedInt num_elem, const CeedOperatorDiag_Sycl *diag, const CeedScalar *assembled_qf_array, CeedScalar *elem_diag_array) { const CeedSize num_nodes = diag->num_nodes; const CeedSize num_qpts = diag->num_qpts; const CeedSize num_comp = diag->num_comp; const CeedSize num_e_mode_in = diag->num_e_mode_in; const CeedSize num_e_mode_out = diag->num_e_mode_out; const CeedScalar *identity = diag->d_identity; const CeedScalar *interp_in = diag->d_interp_in; const CeedScalar *grad_in = diag->d_grad_in; const CeedScalar *interp_out = diag->d_interp_out; const CeedScalar *grad_out = diag->d_grad_out; const CeedEvalMode *e_mode_in = diag->d_e_mode_in; const CeedEvalMode *e_mode_out = diag->d_e_mode_out; sycl::range<1> kernel_range(num_elem * num_nodes); // Order queue sycl::event e = sycl_queue.ext_oneapi_submit_barrier(); sycl_queue.parallel_for(kernel_range, {e}, [=](sycl::id<1> idx) { const CeedInt tid = idx % num_nodes; const CeedInt e = idx / num_nodes; // Compute the diagonal of B^T D B // Each element CeedInt d_out = -1; // Each basis eval mode pair for (CeedSize e_out = 0; e_out < num_e_mode_out; e_out++) { const CeedScalar *bt = NULL; if (e_mode_out[e_out] == CEED_EVAL_GRAD) ++d_out; CeedOperatorGetBasisPointer_Sycl(&bt, e_mode_out[e_out], identity, interp_out, &grad_out[d_out * num_qpts * num_nodes]); CeedInt d_in = -1; for (CeedSize e_in = 0; e_in < num_e_mode_in; e_in++) { const CeedScalar *b = NULL; if (e_mode_in[e_in] == CEED_EVAL_GRAD) ++d_in; CeedOperatorGetBasisPointer_Sycl(&b, e_mode_in[e_in], identity, interp_in, &grad_in[d_in * num_qpts * num_nodes]); // Each component for (CeedSize comp_out = 0; comp_out < num_comp; comp_out++) { // Each qpoint/node pair if (is_point_block) { // Point Block Diagonal for (CeedInt comp_in = 0; comp_in < num_comp; comp_in++) { CeedScalar e_value = 0.0; for (CeedSize q = 0; q < num_qpts; q++) { const CeedScalar qf_value = assembled_qf_array[((((e_in * num_comp + comp_in) * num_e_mode_out + e_out) * num_comp + comp_out) * num_elem + e) * num_qpts + q]; e_value += bt[q * num_nodes + tid] * qf_value * b[q * num_nodes + tid]; } elem_diag_array[((comp_out * num_comp + comp_in) * num_elem + e) * num_nodes + tid] += e_value; } } else { // Diagonal Only CeedScalar e_value = 0.0; for (CeedSize q = 0; q < num_qpts; q++) { const CeedScalar qf_value = assembled_qf_array[((((e_in * num_comp + comp_out) * num_e_mode_out + e_out) * num_comp + comp_out) * num_elem + e) * num_qpts + q]; e_value += bt[q * num_nodes + tid] * qf_value * b[q * num_nodes + tid]; } elem_diag_array[(comp_out * num_elem + e) * num_nodes + tid] += e_value; } } } } }); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Assemble diagonal common code //------------------------------------------------------------------------------ static inline int CeedOperatorAssembleDiagonalCore_Sycl(CeedOperator op, CeedVector assembled, CeedRequest *request, const bool is_point_block) { Ceed ceed; Ceed_Sycl *sycl_data; CeedInt num_elem; CeedScalar *elem_diag_array; const CeedScalar *assembled_qf_array; CeedVector assembled_qf = NULL; CeedElemRestriction rstr = NULL; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedGetData(ceed, &sycl_data)); // Assemble QFunction CeedCallBackend(CeedOperatorLinearAssembleQFunctionBuildOrUpdate(op, &assembled_qf, &rstr, request)); CeedCallBackend(CeedElemRestrictionDestroy(&rstr)); // Setup if (!impl->diag) { CeedCallBackend(CeedOperatorAssembleDiagonalSetup_Sycl(op, is_point_block)); } CeedOperatorDiag_Sycl *diag = impl->diag; assert(diag != NULL); // Restriction if (is_point_block && !diag->point_block_diag_rstr) { CeedElemRestriction point_block_diag_rstr; CeedCallBackend(CreatePBRestriction(diag->diag_rstr, &point_block_diag_rstr)); diag->point_block_diag_rstr = point_block_diag_rstr; } CeedElemRestriction diag_rstr = is_point_block ? diag->point_block_diag_rstr : diag->diag_rstr; // Create diagonal vector CeedVector elem_diag = is_point_block ? diag->point_block_elem_diag : diag->elem_diag; if (!elem_diag) { CeedCallBackend(CeedElemRestrictionCreateVector(diag_rstr, NULL, &elem_diag)); if (is_point_block) diag->point_block_elem_diag = elem_diag; else diag->elem_diag = elem_diag; } CeedCallBackend(CeedVectorSetValue(elem_diag, 0.0)); // Assemble element operator diagonals CeedCallBackend(CeedVectorGetArray(elem_diag, CEED_MEM_DEVICE, &elem_diag_array)); CeedCallBackend(CeedVectorGetArrayRead(assembled_qf, CEED_MEM_DEVICE, &assembled_qf_array)); CeedCallBackend(CeedElemRestrictionGetNumElements(diag_rstr, &num_elem)); // Compute the diagonal of B^T D B // Umesh: This needs to be reviewed later // if (is_point_block) { // CeedCallBackend(CeedOperatorLinearPointBlockDiagonal_Sycl(sycl_data->sycl_queue, num_elem, diag, assembled_qf_array, elem_diag_array)); //} else { CeedCallBackend(CeedOperatorLinearDiagonal_Sycl(sycl_data->sycl_queue, is_point_block, num_elem, diag, assembled_qf_array, elem_diag_array)); // } // Wait for queue to complete and handle exceptions sycl_data->sycl_queue.wait_and_throw(); // Restore arrays CeedCallBackend(CeedVectorRestoreArray(elem_diag, &elem_diag_array)); CeedCallBackend(CeedVectorRestoreArrayRead(assembled_qf, &assembled_qf_array)); // Assemble local operator diagonal CeedCallBackend(CeedElemRestrictionApply(diag_rstr, CEED_TRANSPOSE, elem_diag, assembled, request)); // Cleanup CeedCallBackend(CeedVectorDestroy(&assembled_qf)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Assemble Linear Diagonal //------------------------------------------------------------------------------ static int CeedOperatorLinearAssembleAddDiagonal_Sycl(CeedOperator op, CeedVector assembled, CeedRequest *request) { CeedCallBackend(CeedOperatorAssembleDiagonalCore_Sycl(op, assembled, request, false)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Assemble Linear Point Block Diagonal //------------------------------------------------------------------------------ static int CeedOperatorLinearAssembleAddPointBlockDiagonal_Sycl(CeedOperator op, CeedVector assembled, CeedRequest *request) { CeedCallBackend(CeedOperatorAssembleDiagonalCore_Sycl(op, assembled, request, true)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Single operator assembly setup //------------------------------------------------------------------------------ static int CeedSingleOperatorAssembleSetup_Sycl(CeedOperator op) { Ceed ceed; CeedInt num_input_fields, num_output_fields, num_e_mode_in = 0, dim = 1, num_B_in_mats_to_load = 0, size_B_in = 0, num_e_mode_out = 0, num_B_out_mats_to_load = 0, size_B_out = 0, num_qpts = 0, elem_size = 0, num_elem, num_comp, mat_start = 0; CeedEvalMode *eval_mode_in = NULL, *eval_mode_out = NULL; const CeedScalar *interp_in, *grad_in; CeedElemRestriction rstr_in = NULL, rstr_out = NULL; CeedBasis basis_in = NULL, basis_out = NULL; CeedQFunctionField *qf_fields; CeedQFunction qf; CeedOperatorField *input_fields, *output_fields; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedOperatorGetData(op, &impl)); // Get input and output fields CeedCallBackend(CeedOperatorGetFields(op, &num_input_fields, &input_fields, &num_output_fields, &output_fields)); // Determine active input basis eval mode CeedCallBackend(CeedOperatorGetQFunction(op, &qf)); CeedCallBackend(CeedQFunctionGetFields(qf, NULL, &qf_fields, NULL, NULL)); // Note that the kernel will treat each dimension of a gradient action separately; // i.e., when an active input has a CEED_EVAL_GRAD mode, num_ e_mode_in will increment by dim. // However, for the purposes of load_ing the B matrices, it will be treated as one mode, and we will load/copy the entire gradient matrix at once, // so num_B_in_mats_to_load will be incremented by 1. for (CeedInt i = 0; i < num_input_fields; i++) { CeedEvalMode eval_mode; CeedVector vec; CeedCallBackend(CeedOperatorFieldGetVector(input_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) { CeedCallBackend(CeedOperatorFieldGetBasis(input_fields[i], &basis_in)); CeedCallBackend(CeedBasisGetDimension(basis_in, &dim)); CeedCallBackend(CeedBasisGetNumQuadraturePoints(basis_in, &num_qpts)); CeedCallBackend(CeedOperatorFieldGetElemRestriction(input_fields[i], &rstr_in)); CeedCallBackend(CeedElemRestrictionGetElementSize(rstr_in, &elem_size)); CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &eval_mode)); if (eval_mode != CEED_EVAL_NONE) { CeedCallBackend(CeedRealloc(num_B_in_mats_to_load + 1, &eval_mode_in)); eval_mode_in[num_B_in_mats_to_load] = eval_mode; num_B_in_mats_to_load += 1; if (eval_mode == CEED_EVAL_GRAD) { num_e_mode_in += dim; size_B_in += dim * elem_size * num_qpts; } else { num_e_mode_in += 1; size_B_in += elem_size * num_qpts; } } } } // Determine active output basis; basis_out and rstr_out only used if same as input, TODO CeedCallBackend(CeedQFunctionGetFields(qf, NULL, NULL, NULL, &qf_fields)); for (CeedInt i = 0; i < num_output_fields; i++) { CeedEvalMode eval_mode; CeedVector vec; CeedCallBackend(CeedOperatorFieldGetVector(output_fields[i], &vec)); if (vec == CEED_VECTOR_ACTIVE) { CeedCallBackend(CeedOperatorFieldGetBasis(output_fields[i], &basis_out)); CeedCallBackend(CeedOperatorFieldGetElemRestriction(output_fields[i], &rstr_out)); if (rstr_out && rstr_out != rstr_in) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "Backend does not implement multi-field non-composite operator assembly"); // LCOV_EXCL_STOP } CeedCallBackend(CeedQFunctionFieldGetEvalMode(qf_fields[i], &eval_mode)); if (eval_mode != CEED_EVAL_NONE) { CeedCallBackend(CeedRealloc(num_B_out_mats_to_load + 1, &eval_mode_out)); eval_mode_out[num_B_out_mats_to_load] = eval_mode; num_B_out_mats_to_load += 1; if (eval_mode == CEED_EVAL_GRAD) { num_e_mode_out += dim; size_B_out += dim * elem_size * num_qpts; } else { num_e_mode_out += 1; size_B_out += elem_size * num_qpts; } } } } if (num_e_mode_in == 0 || num_e_mode_out == 0) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_UNSUPPORTED, "Cannot assemble operator without inputs/outputs"); // LCOV_EXCL_STOP } CeedCallBackend(CeedElemRestrictionGetNumElements(rstr_in, &num_elem)); CeedCallBackend(CeedElemRestrictionGetNumComponents(rstr_in, &num_comp)); CeedCallBackend(CeedCalloc(1, &impl->asmb)); CeedOperatorAssemble_Sycl *asmb = impl->asmb; asmb->num_elem = num_elem; Ceed_Sycl *sycl_data; CeedCallBackend(CeedGetData(ceed, &sycl_data)); // Kernel setup int elem_per_block = 1; asmb->elem_per_block = elem_per_block; CeedInt block_size = elem_size * elem_size * elem_per_block; /* CeedInt maxThreadsPerBlock = sycl_data->sycl_device.get_info(); bool fallback = block_size > maxThreadsPerBlock; asmb->fallback = fallback; if (fallback) { // Use fallback kernel with 1D threadblock block_size = elem_size * elem_per_block; asmb->block_size_x = elem_size; asmb->block_size_y = 1; } else { // Use kernel with 2D threadblock asmb->block_size_x = elem_size; asmb->block_size_y = elem_size; }*/ asmb->block_size_x = elem_size; asmb->block_size_y = elem_size; asmb->num_e_mode_in = num_e_mode_in; asmb->num_e_mode_out = num_e_mode_out; asmb->num_qpts = num_qpts; asmb->num_nodes = elem_size; asmb->block_size = block_size; asmb->num_comp = num_comp; // Build 'full' B matrices (not 1D arrays used for tensor-product matrices CeedCallBackend(CeedBasisGetInterp(basis_in, &interp_in)); CeedCallBackend(CeedBasisGetGrad(basis_in, &grad_in)); // Load into B_in, in order that they will be used in eval_mode CeedCallSycl(ceed, asmb->d_B_in = sycl::malloc_device(size_B_in, sycl_data->sycl_device, sycl_data->sycl_context)); for (int i = 0; i < num_B_in_mats_to_load; i++) { CeedEvalMode eval_mode = eval_mode_in[i]; if (eval_mode == CEED_EVAL_INTERP) { // Order queue sycl::event e = sycl_data->sycl_queue.ext_oneapi_submit_barrier(); sycl_data->sycl_queue.copy(interp_in, &asmb->d_B_in[mat_start], elem_size * num_qpts, {e}); mat_start += elem_size * num_qpts; } else if (eval_mode == CEED_EVAL_GRAD) { // Order queue sycl::event e = sycl_data->sycl_queue.ext_oneapi_submit_barrier(); sycl_data->sycl_queue.copy(grad_in, &asmb->d_B_in[mat_start], dim * elem_size * num_qpts, {e}); mat_start += dim * elem_size * num_qpts; } } const CeedScalar *interp_out, *grad_out; // Note that this function currently assumes 1 basis, so this should always be true // for now if (basis_out == basis_in) { interp_out = interp_in; grad_out = grad_in; } else { CeedCallBackend(CeedBasisGetInterp(basis_out, &interp_out)); CeedCallBackend(CeedBasisGetGrad(basis_out, &grad_out)); } // Load into B_out, in order that they will be used in eval_mode mat_start = 0; CeedCallSycl(ceed, asmb->d_B_out = sycl::malloc_device(size_B_out, sycl_data->sycl_device, sycl_data->sycl_context)); for (int i = 0; i < num_B_out_mats_to_load; i++) { CeedEvalMode eval_mode = eval_mode_out[i]; if (eval_mode == CEED_EVAL_INTERP) { // Order queue sycl::event e = sycl_data->sycl_queue.ext_oneapi_submit_barrier(); sycl_data->sycl_queue.copy(interp_out, &asmb->d_B_out[mat_start], elem_size * num_qpts, {e}); mat_start += elem_size * num_qpts; } else if (eval_mode == CEED_EVAL_GRAD) { // Order queue sycl::event e = sycl_data->sycl_queue.ext_oneapi_submit_barrier(); sycl_data->sycl_queue.copy(grad_out, &asmb->d_B_out[mat_start], dim * elem_size * num_qpts, {e}); mat_start += dim * elem_size * num_qpts; } } return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Matrix assembly kernel for low-order elements (3D thread block) //------------------------------------------------------------------------------ static int CeedOperatorLinearAssemble_Sycl(sycl::queue &sycl_queue, const CeedOperator_Sycl *impl, const CeedScalar *qf_array, CeedScalar *values_array) { // This kernels assumes B_in and B_out have the same number of quadrature points and basis points. // TODO: expand to more general cases CeedOperatorAssemble_Sycl *asmb = impl->asmb; const CeedInt num_elem = asmb->num_elem; const CeedSize num_nodes = asmb->num_nodes; const CeedSize num_comp = asmb->num_comp; const CeedSize num_qpts = asmb->num_qpts; const CeedSize num_e_mode_in = asmb->num_e_mode_in; const CeedSize num_e_mode_out = asmb->num_e_mode_out; // Strides for final output ordering, determined by the reference (inference) implementation of the symbolic assembly, slowest --> fastest: element, // comp_in, comp_out, node_row, node_col const CeedSize comp_out_stride = num_nodes * num_nodes; const CeedSize comp_in_stride = comp_out_stride * num_comp; const CeedSize e_stride = comp_in_stride * num_comp; // Strides for QF array, slowest --> fastest: e_mode_in, comp_in, e_mode_out, comp_out, elem, qpt const CeedSize q_e_stride = num_qpts; const CeedSize q_comp_out_stride = num_elem * q_e_stride; const CeedSize q_e_mode_out_stride = q_comp_out_stride * num_comp; const CeedSize q_comp_in_stride = q_e_mode_out_stride * num_e_mode_out; const CeedSize q_e_mode_in_stride = q_comp_in_stride * num_comp; CeedScalar *B_in, *B_out; B_in = asmb->d_B_in; B_out = asmb->d_B_out; const CeedInt block_size_x = asmb->block_size_x; const CeedInt block_size_y = asmb->block_size_y; sycl::range<3> kernel_range(num_elem, block_size_y, block_size_x); // Order queue sycl::event e = sycl_queue.ext_oneapi_submit_barrier(); sycl_queue.parallel_for(kernel_range, {e}, [=](sycl::id<3> idx) { const int e = idx.get(0); // Element index const int l = idx.get(1); // The output column index of each B^TDB operation const int i = idx.get(2); // The output row index of each B^TDB operation // such that we have (Bout^T)_ij D_jk Bin_kl = C_il for (CeedSize comp_in = 0; comp_in < num_comp; comp_in++) { for (CeedSize comp_out = 0; comp_out < num_comp; comp_out++) { CeedScalar result = 0.0; CeedSize qf_index_comp = q_comp_in_stride * comp_in + q_comp_out_stride * comp_out + q_e_stride * e; for (CeedSize e_mode_in = 0; e_mode_in < num_e_mode_in; e_mode_in++) { CeedSize b_in_index = e_mode_in * num_qpts * num_nodes; for (CeedSize e_mode_out = 0; e_mode_out < num_e_mode_out; e_mode_out++) { CeedSize b_out_index = e_mode_out * num_qpts * num_nodes; CeedSize qf_index = qf_index_comp + q_e_mode_out_stride * e_mode_out + q_e_mode_in_stride * e_mode_in; // Perform the B^T D B operation for this 'chunk' of D (the qf_array) for (CeedSize j = 0; j < num_qpts; j++) { result += B_out[b_out_index + j * num_nodes + i] * qf_array[qf_index + j] * B_in[b_in_index + j * num_nodes + l]; } } // end of e_mode_out } // end of e_mode_in CeedSize val_index = comp_in_stride * comp_in + comp_out_stride * comp_out + e_stride * e + num_nodes * i + l; values_array[val_index] = result; } // end of out component } // end of in component }); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Fallback kernel for larger orders (1D thread block) //------------------------------------------------------------------------------ /* static int CeedOperatorLinearAssembleFallback_Sycl(sycl::queue &sycl_queue, const CeedOperator_Sycl *impl, const CeedScalar *qf_array, CeedScalar *values_array) { // This kernel assumes B_in and B_out have the same number of quadrature points and basis points. // TODO: expand to more general cases CeedOperatorAssemble_Sycl *asmb = impl->asmb; const CeedInt num_elem = asmb->num_elem; const CeedInt num_nodes = asmb->num_nodes; const CeedInt num_comp = asmb->num_comp; const CeedInt num_qpts = asmb->num_qpts; const CeedInt num_e_mode_in = asmb->num_e_mode_in; const CeedInt num_e_mode_out = asmb->num_e_mode_out; // Strides for final output ordering, determined by the reference (interface) implementation of the symbolic assembly, slowest --> fastest: elememt, // comp_in, comp_out, node_row, node_col const CeedInt comp_out_stride = num_nodes * num_nodes; const CeedInt comp_in_stride = comp_out_stride * num_comp; const CeedInt e_stride = comp_in_stride * num_comp; // Strides for QF array, slowest --> fastest: e_mode_in, comp_in, e_mode_out, comp_out, elem, qpt const CeedInt q_e_stride = num_qpts; const CeedInt q_comp_out_stride = num_elem * q_e_stride; const CeedInt q_e_mode_out_stride = q_comp_out_stride * num_comp; const CeedInt q_comp_in_stride = q_e_mode_out_stride * num_e_mode_out; const CeedInt q_e_mode_in_stride = q_comp_in_stride * num_comp; CeedScalar *B_in, *B_out; B_in = asmb->d_B_in; B_out = asmb->d_B_out; const CeedInt elem_per_block = asmb->elem_per_block; const CeedInt block_size_x = asmb->block_size_x; const CeedInt block_size_y = asmb->block_size_y; // This will be 1 for the fallback kernel const CeedInt grid = num_elem / elem_per_block + ((num_elem / elem_per_block * elem_per_block < num_elem) ? 1 : 0); sycl::range<3> local_range(block_size_x, block_size_y, elem_per_block); sycl::range<3> global_range(grid * block_size_x, block_size_y, elem_per_block); sycl::nd_range<3> kernel_range(global_range, local_range); sycl_queue.parallel_for(kernel_range, [=](sycl::nd_item<3> work_item) { const CeedInt blockIdx = work_item.get_group(0); const CeedInt gridDimx = work_item.get_group_range(0); const CeedInt threadIdx = work_item.get_local_id(0); const CeedInt threadIdz = work_item.get_local_id(2); const CeedInt blockDimz = work_item.get_local_range(2); const int l = threadIdx; // The output column index of each B^TDB operation // such that we have (Bout^T)_ij D_jk Bin_kl = C_il for (CeedInt e = blockIdx * blockDimz + threadIdz; e < num_elem; e += gridDimx * blockDimz) { for (CeedInt comp_in = 0; comp_in < num_comp; comp_in++) { for (CeedInt comp_out = 0; comp_out < num_comp; comp_out++) { for (CeedInt i = 0; i < num_nodes; i++) { CeedScalar result = 0.0; CeedInt qf_index_comp = q_comp_in_stride * comp_in + q_comp_out_stride * comp_out + q_e_stride * e; for (CeedInt e_mode_in = 0; e_mode_in < num_e_mode_in; e_mode_in++) { CeedInt b_in_index = e_mode_in * num_qpts * num_nodes; for (CeedInt e_mode_out = 0; e_mode_out < num_e_mode_out; e_mode_out++) { CeedInt b_out_index = e_mode_out * num_qpts * num_nodes; CeedInt qf_index = qf_index_comp + q_e_mode_out_stride * e_mode_out + q_e_mode_in_stride * e_mode_in; // Perform the B^T D B operation for this 'chunk' of D (the qf_array) for (CeedInt j = 0; j < num_qpts; j++) { result += B_out[b_out_index + j * num_nodes + i] * qf_array[qf_index + j] * B_in[b_in_index + j * num_nodes + l]; } } // end of e_mode_out } // end of e_mode_in CeedInt val_index = comp_in_stride * comp_in + comp_out_stride * comp_out + e_stride * e + num_nodes * i + l; values_array[val_index] = result; } // end of loop over element node index, i } // end of out component } // end of in component } // end of element loop }); return CEED_ERROR_SUCCESS; }*/ //------------------------------------------------------------------------------ // Assemble matrix data for COO matrix of assembled operator. // The sparsity pattern is set by CeedOperatorLinearAssembleSymbolic. // // Note that this (and other assembly routines) currently assume only one active // input restriction/basis per operator (could have multiple basis eval modes). // TODO: allow multiple active input restrictions/basis objects //------------------------------------------------------------------------------ static int CeedSingleOperatorAssemble_Sycl(CeedOperator op, CeedInt offset, CeedVector values) { Ceed ceed; Ceed_Sycl *sycl_data; CeedScalar *values_array; const CeedScalar *qf_array; CeedVector assembled_qf = NULL; CeedElemRestriction rstr_q = NULL; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedOperatorGetData(op, &impl)); CeedCallBackend(CeedGetData(ceed, &sycl_data)); // Setup if (!impl->asmb) { CeedCallBackend(CeedSingleOperatorAssembleSetup_Sycl(op)); assert(impl->asmb != NULL); } // Assemble QFunction CeedCallBackend(CeedOperatorLinearAssembleQFunctionBuildOrUpdate(op, &assembled_qf, &rstr_q, CEED_REQUEST_IMMEDIATE)); CeedCallBackend(CeedElemRestrictionDestroy(&rstr_q)); CeedCallBackend(CeedVectorGetArrayWrite(values, CEED_MEM_DEVICE, &values_array)); values_array += offset; CeedCallBackend(CeedVectorGetArrayRead(assembled_qf, CEED_MEM_DEVICE, &qf_array)); // Compute B^T D B CeedCallBackend(CeedOperatorLinearAssemble_Sycl(sycl_data->sycl_queue, impl, qf_array, values_array)); // Wait for kernels to be completed // Kris: Review if this is necessary -- enqueing an async barrier may be sufficient sycl_data->sycl_queue.wait_and_throw(); // Restore arrays CeedCallBackend(CeedVectorRestoreArray(values, &values_array)); CeedCallBackend(CeedVectorRestoreArrayRead(assembled_qf, &qf_array)); // Cleanup CeedCallBackend(CeedVectorDestroy(&assembled_qf)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------ // Create operator //------------------------------------------------------------------------------ int CeedOperatorCreate_Sycl(CeedOperator op) { Ceed ceed; CeedOperator_Sycl *impl; CeedCallBackend(CeedOperatorGetCeed(op, &ceed)); CeedCallBackend(CeedCalloc(1, &impl)); CeedCallBackend(CeedOperatorSetData(op, impl)); CeedCallBackend(CeedSetBackendFunctionCpp(ceed, "Operator", op, "LinearAssembleQFunction", CeedOperatorLinearAssembleQFunction_Sycl)); CeedCallBackend(CeedSetBackendFunctionCpp(ceed, "Operator", op, "LinearAssembleQFunctionUpdate", CeedOperatorLinearAssembleQFunctionUpdate_Sycl)); CeedCallBackend(CeedSetBackendFunctionCpp(ceed, "Operator", op, "LinearAssembleAddDiagonal", CeedOperatorLinearAssembleAddDiagonal_Sycl)); CeedCallBackend( CeedSetBackendFunctionCpp(ceed, "Operator", op, "LinearAssembleAddPointBlockDiagonal", CeedOperatorLinearAssembleAddPointBlockDiagonal_Sycl)); CeedCallBackend(CeedSetBackendFunctionCpp(ceed, "Operator", op, "LinearAssembleSingle", CeedSingleOperatorAssemble_Sycl)); CeedCallBackend(CeedSetBackendFunctionCpp(ceed, "Operator", op, "ApplyAdd", CeedOperatorApplyAdd_Sycl)); CeedCallBackend(CeedSetBackendFunctionCpp(ceed, "Operator", op, "Destroy", CeedOperatorDestroy_Sycl)); return CEED_ERROR_SUCCESS; } //------------------------------------------------------------------------------