// 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 "ceed-magma.h" #ifdef CEED_MAGMA_USE_HIP #include "../hip/ceed-hip-common.h" #include "../hip/ceed-hip-compile.h" #else #include "../cuda/ceed-cuda-common.h" #include "../cuda/ceed-cuda-compile.h" #endif #ifdef __cplusplus CEED_INTERN "C" #endif int CeedBasisApply_Magma(CeedBasis basis, CeedInt nelem, CeedTransposeMode tmode, CeedEvalMode emode, CeedVector U, CeedVector V) { int ierr; Ceed ceed; ierr = CeedBasisGetCeed(basis, &ceed); CeedChkBackend(ierr); CeedInt dim, ncomp, ndof; ierr = CeedBasisGetDimension(basis, &dim); CeedChkBackend(ierr); ierr = CeedBasisGetNumComponents(basis, &ncomp); CeedChkBackend(ierr); ierr = CeedBasisGetNumNodes(basis, &ndof); CeedChkBackend(ierr); Ceed_Magma *data; ierr = CeedGetData(ceed, &data); CeedChkBackend(ierr); const CeedScalar *u; CeedScalar *v; if (emode != CEED_EVAL_WEIGHT) { ierr = CeedVectorGetArrayRead(U, CEED_MEM_DEVICE, &u); CeedChkBackend(ierr); } else if (emode != CEED_EVAL_WEIGHT) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "An input vector is required for this CeedEvalMode"); // LCOV_EXCL_STOP } ierr = CeedVectorGetArrayWrite(V, CEED_MEM_DEVICE, &v); CeedChkBackend(ierr); CeedBasis_Magma *impl; ierr = CeedBasisGetData(basis, &impl); CeedChkBackend(ierr); CeedInt P1d, Q1d; ierr = CeedBasisGetNumNodes1D(basis, &P1d); CeedChkBackend(ierr); ierr = CeedBasisGetNumQuadraturePoints1D(basis, &Q1d); CeedChkBackend(ierr); CeedDebug(ceed, "\033[01m[CeedBasisApply_Magma] vsize=%d, comp = %d", ncomp*CeedIntPow(P1d, dim), ncomp); if (tmode == CEED_TRANSPOSE) { CeedSize length; ierr = CeedVectorGetLength(V, &length); CeedChkBackend(ierr); if (CEED_SCALAR_TYPE == CEED_SCALAR_FP32) { magmablas_slaset(MagmaFull, length, 1, 0., 0., (float *) v, length, data->queue); } else { magmablas_dlaset(MagmaFull, length, 1, 0., 0., (double *) v, length, data->queue); } ceed_magma_queue_sync( data->queue ); } switch (emode) { case CEED_EVAL_INTERP: { CeedInt P = P1d, Q = Q1d; if (tmode == CEED_TRANSPOSE) { P = Q1d; Q = P1d; } // Define element sizes for dofs/quad CeedInt elquadsize = CeedIntPow(Q1d, dim); CeedInt eldofssize = CeedIntPow(P1d, dim); // E-vector ordering -------------- Q-vector ordering // component component // elem elem // node node // --- Define strides for NOTRANSPOSE mode: --- // Input (u) is E-vector, output (v) is Q-vector // Element strides CeedInt u_elstride = eldofssize; CeedInt v_elstride = elquadsize; // Component strides CeedInt u_compstride = nelem * eldofssize; CeedInt v_compstride = nelem * elquadsize; // --- Swap strides for TRANSPOSE mode: --- if (tmode == CEED_TRANSPOSE) { // Input (u) is Q-vector, output (v) is E-vector // Element strides v_elstride = eldofssize; u_elstride = elquadsize; // Component strides v_compstride = nelem * eldofssize; u_compstride = nelem * elquadsize; } CeedInt nthreads = 1; CeedInt ntcol = 1; CeedInt shmem = 0; CeedInt maxPQ = CeedIntMax(P, Q); switch (dim) { case 1: nthreads = maxPQ; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_1D); shmem += sizeof(CeedScalar) * ntcol * ( ncomp * (1*P + 1*Q) ); shmem += sizeof(CeedScalar) * (P*Q); break; case 2: nthreads = maxPQ; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_2D); shmem += P*Q *sizeof(CeedScalar); // for sT shmem += ntcol * ( P*maxPQ*sizeof( CeedScalar) ); // for reforming rU we need PxP, and for the intermediate output we need PxQ break; case 3: nthreads = maxPQ*maxPQ; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_3D); shmem += sizeof(CeedScalar)* (P*Q); // for sT shmem += sizeof(CeedScalar)* ntcol * (CeedIntMax(P*P*maxPQ, P*Q*Q)); // rU needs P^2xP, the intermediate output needs max(P^2xQ,PQ^2) } CeedInt grid = (nelem + ntcol-1) / ntcol; void *args[] = {&impl->dinterp1d, &u, &u_elstride, &u_compstride, &v, &v_elstride, &v_compstride, &nelem }; if (tmode == CEED_TRANSPOSE) { ierr = MAGMA_RTC_RUN_KERNEL_DIM_SH(ceed, impl->magma_interp_tr, grid, nthreads, ntcol, 1, shmem, args); CeedChkBackend(ierr); } else { ierr = MAGMA_RTC_RUN_KERNEL_DIM_SH(ceed, impl->magma_interp, grid, nthreads, ntcol, 1, shmem, args); CeedChkBackend(ierr); } } break; case CEED_EVAL_GRAD: { CeedInt P = P1d, Q = Q1d; // In CEED_NOTRANSPOSE mode: // u is (P^dim x nc), column-major layout (nc = ncomp) // v is (Q^dim x nc x dim), column-major layout (nc = ncomp) // In CEED_TRANSPOSE mode, the sizes of u and v are switched. if (tmode == CEED_TRANSPOSE) { P = Q1d, Q = P1d; } // Define element sizes for dofs/quad CeedInt elquadsize = CeedIntPow(Q1d, dim); CeedInt eldofssize = CeedIntPow(P1d, dim); // E-vector ordering -------------- Q-vector ordering // dim // component component // elem elem // node node // --- Define strides for NOTRANSPOSE mode: --- // Input (u) is E-vector, output (v) is Q-vector // Element strides CeedInt u_elstride = eldofssize; CeedInt v_elstride = elquadsize; // Component strides CeedInt u_compstride = nelem * eldofssize; CeedInt v_compstride = nelem * elquadsize; // Dimension strides CeedInt u_dimstride = 0; CeedInt v_dimstride = nelem * elquadsize * ncomp; // --- Swap strides for TRANSPOSE mode: --- if (tmode == CEED_TRANSPOSE) { // Input (u) is Q-vector, output (v) is E-vector // Element strides v_elstride = eldofssize; u_elstride = elquadsize; // Component strides v_compstride = nelem * eldofssize; u_compstride = nelem * elquadsize; // Dimension strides v_dimstride = 0; u_dimstride = nelem * elquadsize * ncomp; } CeedInt nthreads = 1; CeedInt ntcol = 1; CeedInt shmem = 0; CeedInt maxPQ = CeedIntMax(P, Q); switch (dim) { case 1: nthreads = maxPQ; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_1D); shmem += sizeof(CeedScalar) * ntcol * (ncomp * (1*P + 1*Q)); shmem += sizeof(CeedScalar) * (P*Q); break; case 2: nthreads = maxPQ; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_2D); shmem += sizeof(CeedScalar) * 2*P*Q; // for sTinterp and sTgrad shmem += sizeof(CeedScalar) * ntcol * (P*maxPQ); // for reforming rU we need PxP, and for the intermediate output we need PxQ break; case 3: nthreads = maxPQ * maxPQ; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_3D); shmem += sizeof(CeedScalar) * 2*P*Q; // for sTinterp and sTgrad shmem += sizeof(CeedScalar) * ntcol * CeedIntMax(P*P*P, (P*P*Q) + (P*Q*Q)); // rU needs P^2xP, the intermediate outputs need (P^2.Q + P.Q^2) } CeedInt grid = (nelem + ntcol-1) / ntcol; void *args[] = {&impl->dinterp1d, &impl->dgrad1d, &u, &u_elstride, &u_compstride, &u_dimstride, &v, &v_elstride, &v_compstride, &v_dimstride, &nelem }; if (tmode == CEED_TRANSPOSE) { ierr = MAGMA_RTC_RUN_KERNEL_DIM_SH(ceed, impl->magma_grad_tr, grid, nthreads, ntcol, 1, shmem, args); CeedChkBackend(ierr); } else { ierr = MAGMA_RTC_RUN_KERNEL_DIM_SH(ceed, impl->magma_grad, grid, nthreads, ntcol, 1, shmem, args); CeedChkBackend(ierr); } } break; case CEED_EVAL_WEIGHT: { if (tmode == CEED_TRANSPOSE) // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_WEIGHT incompatible with CEED_TRANSPOSE"); // LCOV_EXCL_STOP CeedInt Q = Q1d; CeedInt eldofssize = CeedIntPow(Q, dim); CeedInt nthreads = 1; CeedInt ntcol = 1; CeedInt shmem = 0; switch (dim) { case 1: nthreads = Q; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_1D); shmem += sizeof(CeedScalar) * Q; // for dqweight1d shmem += sizeof(CeedScalar) * ntcol * Q; // for output break; case 2: nthreads = Q; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_2D); shmem += sizeof(CeedScalar) * Q; // for dqweight1d break; case 3: nthreads = Q * Q; ntcol = MAGMA_BASIS_NTCOL(nthreads, MAGMA_MAXTHREADS_3D); shmem += sizeof(CeedScalar) * Q; // for dqweight1d } CeedInt grid = (nelem + ntcol-1) / ntcol; void *args[] = {&impl->dqweight1d, &v, &eldofssize, &nelem}; ierr = MAGMA_RTC_RUN_KERNEL_DIM_SH(ceed, impl->magma_weight, grid, nthreads, ntcol, 1, shmem, args); CeedChkBackend(ierr); } break; // LCOV_EXCL_START case CEED_EVAL_DIV: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_DIV not supported"); case CEED_EVAL_CURL: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_CURL not supported"); case CEED_EVAL_NONE: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_NONE does not make sense in this context"); // LCOV_EXCL_STOP } // must sync to ensure completeness ceed_magma_queue_sync( data->queue ); if (emode!=CEED_EVAL_WEIGHT) { ierr = CeedVectorRestoreArrayRead(U, &u); CeedChkBackend(ierr); } ierr = CeedVectorRestoreArray(V, &v); CeedChkBackend(ierr); return CEED_ERROR_SUCCESS; } #ifdef __cplusplus CEED_INTERN "C" #endif int CeedBasisApplyNonTensor_f64_Magma(CeedBasis basis, CeedInt nelem, CeedTransposeMode tmode, CeedEvalMode emode, CeedVector U, CeedVector V) { int ierr; Ceed ceed; ierr = CeedBasisGetCeed(basis, &ceed); CeedChkBackend(ierr); Ceed_Magma *data; ierr = CeedGetData(ceed, &data); CeedChkBackend(ierr); CeedInt dim, ncomp, ndof, nqpt; ierr = CeedBasisGetDimension(basis, &dim); CeedChkBackend(ierr); ierr = CeedBasisGetNumComponents(basis, &ncomp); CeedChkBackend(ierr); ierr = CeedBasisGetNumNodes(basis, &ndof); CeedChkBackend(ierr); ierr = CeedBasisGetNumQuadraturePoints(basis, &nqpt); CeedChkBackend(ierr); const CeedScalar *du; CeedScalar *dv; if (emode != CEED_EVAL_WEIGHT) { ierr = CeedVectorGetArrayRead(U, CEED_MEM_DEVICE, &du); CeedChkBackend(ierr); } else if (emode != CEED_EVAL_WEIGHT) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "An input vector is required for this CeedEvalMode"); // LCOV_EXCL_STOP } ierr = CeedVectorGetArrayWrite(V, CEED_MEM_DEVICE, &dv); CeedChkBackend(ierr); CeedBasisNonTensor_Magma *impl; ierr = CeedBasisGetData(basis, &impl); CeedChkBackend(ierr); CeedDebug(ceed, "\033[01m[CeedBasisApplyNonTensor_Magma] vsize=%d, comp = %d", ncomp*ndof, ncomp); if (tmode == CEED_TRANSPOSE) { CeedSize length; ierr = CeedVectorGetLength(V, &length); if (CEED_SCALAR_TYPE == CEED_SCALAR_FP32) { magmablas_slaset(MagmaFull, length, 1, 0., 0., (float *) dv, length, data->queue); } else { magmablas_dlaset(MagmaFull, length, 1, 0., 0., (double *) dv, length, data->queue); } ceed_magma_queue_sync( data->queue ); } switch (emode) { case CEED_EVAL_INTERP: { CeedInt P = ndof, Q = nqpt; if (tmode == CEED_TRANSPOSE) magma_dgemm_nontensor(MagmaNoTrans, MagmaNoTrans, P, nelem*ncomp, Q, 1.0, (double *)impl->dinterp, P, (double *)du, Q, 0.0, (double *)dv, P, data->queue); else magma_dgemm_nontensor(MagmaTrans, MagmaNoTrans, Q, nelem*ncomp, P, 1.0, (double *)impl->dinterp, P, (double *)du, P, 0.0, (double *)dv, Q, data->queue); } break; case CEED_EVAL_GRAD: { CeedInt P = ndof, Q = nqpt; if (tmode == CEED_TRANSPOSE) { CeedScalar beta = 0.0; for(int d=0; d0) beta = 1.0; magma_dgemm_nontensor(MagmaNoTrans, MagmaNoTrans, P, nelem*ncomp, Q, 1.0, (double *)(impl->dgrad + d*P*Q), P, (double *)(du + d*nelem*ncomp*Q), Q, beta, (double *)dv, P, data->queue); } } else { for(int d=0; d< dim; d++) magma_dgemm_nontensor(MagmaTrans, MagmaNoTrans, Q, nelem*ncomp, P, 1.0, (double *)(impl->dgrad + d*P*Q), P, (double *)du, P, 0.0, (double *)(dv + d*nelem*ncomp*Q), Q, data->queue); } } break; case CEED_EVAL_WEIGHT: { if (tmode == CEED_TRANSPOSE) // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_WEIGHT incompatible with CEED_TRANSPOSE"); // LCOV_EXCL_STOP int elemsPerBlock = 1;//basis->Q1d < 7 ? optElems[basis->Q1d] : 1; int grid = nelem/elemsPerBlock + ( (nelem/elemsPerBlock*elemsPerBlockdqweight, dv, data->queue); CeedChkBackend(ierr); } break; // LCOV_EXCL_START case CEED_EVAL_DIV: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_DIV not supported"); case CEED_EVAL_CURL: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_CURL not supported"); case CEED_EVAL_NONE: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_NONE does not make sense in this context"); // LCOV_EXCL_STOP } // must sync to ensure completeness ceed_magma_queue_sync( data->queue ); if (emode!=CEED_EVAL_WEIGHT) { ierr = CeedVectorRestoreArrayRead(U, &du); CeedChkBackend(ierr); } ierr = CeedVectorRestoreArray(V, &dv); CeedChkBackend(ierr); return CEED_ERROR_SUCCESS; } int CeedBasisApplyNonTensor_f32_Magma(CeedBasis basis, CeedInt nelem, CeedTransposeMode tmode, CeedEvalMode emode, CeedVector U, CeedVector V) { int ierr; Ceed ceed; ierr = CeedBasisGetCeed(basis, &ceed); CeedChkBackend(ierr); Ceed_Magma *data; ierr = CeedGetData(ceed, &data); CeedChkBackend(ierr); CeedInt dim, ncomp, ndof, nqpt; ierr = CeedBasisGetDimension(basis, &dim); CeedChkBackend(ierr); ierr = CeedBasisGetNumComponents(basis, &ncomp); CeedChkBackend(ierr); ierr = CeedBasisGetNumNodes(basis, &ndof); CeedChkBackend(ierr); ierr = CeedBasisGetNumQuadraturePoints(basis, &nqpt); CeedChkBackend(ierr); const CeedScalar *du; CeedScalar *dv; if (emode != CEED_EVAL_WEIGHT) { ierr = CeedVectorGetArrayRead(U, CEED_MEM_DEVICE, &du); CeedChkBackend(ierr); } else if (emode != CEED_EVAL_WEIGHT) { // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "An input vector is required for this CeedEvalMode"); // LCOV_EXCL_STOP } ierr = CeedVectorGetArrayWrite(V, CEED_MEM_DEVICE, &dv); CeedChkBackend(ierr); CeedBasisNonTensor_Magma *impl; ierr = CeedBasisGetData(basis, &impl); CeedChkBackend(ierr); CeedDebug(ceed, "\033[01m[CeedBasisApplyNonTensor_Magma] vsize=%d, comp = %d", ncomp*ndof, ncomp); if (tmode == CEED_TRANSPOSE) { CeedSize length; ierr = CeedVectorGetLength(V, &length); if (CEED_SCALAR_TYPE == CEED_SCALAR_FP32) { magmablas_slaset(MagmaFull, length, 1, 0., 0., (float *) dv, length, data->queue); } else { magmablas_dlaset(MagmaFull, length, 1, 0., 0., (double *) dv, length, data->queue); } ceed_magma_queue_sync( data->queue ); } switch (emode) { case CEED_EVAL_INTERP: { CeedInt P = ndof, Q = nqpt; if (tmode == CEED_TRANSPOSE) magma_sgemm_nontensor(MagmaNoTrans, MagmaNoTrans, P, nelem*ncomp, Q, 1.0, (float *)impl->dinterp, P, (float *)du, Q, 0.0, (float *)dv, P, data->queue); else magma_sgemm_nontensor(MagmaTrans, MagmaNoTrans, Q, nelem*ncomp, P, 1.0, (float *)impl->dinterp, P, (float *)du, P, 0.0, (float *)dv, Q, data->queue); } break; case CEED_EVAL_GRAD: { CeedInt P = ndof, Q = nqpt; if (tmode == CEED_TRANSPOSE) { CeedScalar beta = 0.0; for(int d=0; d0) beta = 1.0; magma_sgemm_nontensor(MagmaNoTrans, MagmaNoTrans, P, nelem*ncomp, Q, 1.0, (float *)(impl->dgrad + d*P*Q), P, (float *)(du + d*nelem*ncomp*Q), Q, beta, (float *)dv, P, data->queue); } } else { for(int d=0; d< dim; d++) magma_sgemm_nontensor(MagmaTrans, MagmaNoTrans, Q, nelem*ncomp, P, 1.0, (float *)(impl->dgrad + d*P*Q), P, (float *)du, P, 0.0, (float *)(dv + d*nelem*ncomp*Q), Q, data->queue); } } break; case CEED_EVAL_WEIGHT: { if (tmode == CEED_TRANSPOSE) // LCOV_EXCL_START return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_WEIGHT incompatible with CEED_TRANSPOSE"); // LCOV_EXCL_STOP int elemsPerBlock = 1;//basis->Q1d < 7 ? optElems[basis->Q1d] : 1; int grid = nelem/elemsPerBlock + ( (nelem/elemsPerBlock*elemsPerBlockdqweight, dv, data->queue); CeedChkBackend(ierr); } break; // LCOV_EXCL_START case CEED_EVAL_DIV: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_DIV not supported"); case CEED_EVAL_CURL: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_CURL not supported"); case CEED_EVAL_NONE: return CeedError(ceed, CEED_ERROR_BACKEND, "CEED_EVAL_NONE does not make sense in this context"); // LCOV_EXCL_STOP } // must sync to ensure completeness ceed_magma_queue_sync( data->queue ); if (emode!=CEED_EVAL_WEIGHT) { ierr = CeedVectorRestoreArrayRead(U, &du); CeedChkBackend(ierr); } ierr = CeedVectorRestoreArray(V, &dv); CeedChkBackend(ierr); return CEED_ERROR_SUCCESS; } #ifdef __cplusplus CEED_INTERN "C" #endif int CeedBasisDestroy_Magma(CeedBasis basis) { int ierr; CeedBasis_Magma *impl; ierr = CeedBasisGetData(basis, &impl); CeedChkBackend(ierr); ierr = magma_free(impl->dqref1d); CeedChkBackend(ierr); ierr = magma_free(impl->dinterp1d); CeedChkBackend(ierr); ierr = magma_free(impl->dgrad1d); CeedChkBackend(ierr); ierr = magma_free(impl->dqweight1d); CeedChkBackend(ierr); Ceed ceed; ierr = CeedBasisGetCeed(basis, &ceed); CeedChkBackend(ierr); #ifdef CEED_MAGMA_USE_HIP ierr = hipModuleUnload(impl->module); CeedChk_Hip(ceed, ierr); #else ierr = cuModuleUnload(impl->module); CeedChk_Cu(ceed, ierr); #endif ierr = CeedFree(&impl); CeedChkBackend(ierr); return CEED_ERROR_SUCCESS; } #ifdef __cplusplus CEED_INTERN "C" #endif int CeedBasisDestroyNonTensor_Magma(CeedBasis basis) { int ierr; CeedBasisNonTensor_Magma *impl; ierr = CeedBasisGetData(basis, &impl); CeedChkBackend(ierr); ierr = magma_free(impl->dqref); CeedChkBackend(ierr); ierr = magma_free(impl->dinterp); CeedChkBackend(ierr); ierr = magma_free(impl->dgrad); CeedChkBackend(ierr); ierr = magma_free(impl->dqweight); CeedChkBackend(ierr); ierr = CeedFree(&impl); CeedChkBackend(ierr); return CEED_ERROR_SUCCESS; } #ifdef __cplusplus CEED_INTERN "C" #endif int CeedBasisCreateTensorH1_Magma(CeedInt dim, CeedInt P1d, CeedInt Q1d, const CeedScalar *interp1d, const CeedScalar *grad1d, const CeedScalar *qref1d, const CeedScalar *qweight1d, CeedBasis basis) { int ierr; CeedBasis_Magma *impl; ierr = CeedCalloc(1,&impl); CeedChkBackend(ierr); Ceed ceed; ierr = CeedBasisGetCeed(basis, &ceed); CeedChkBackend(ierr); // Check for supported parameters CeedInt ncomp = 0; ierr = CeedBasisGetNumComponents(basis, &ncomp); CeedChkBackend(ierr); Ceed_Magma *data; ierr = CeedGetData(ceed, &data); CeedChkBackend(ierr); // Compile kernels char *magma_common_path; char *interp_path, *grad_path, *weight_path; char *basis_kernel_source; ierr = CeedGetJitAbsolutePath(ceed, "ceed/jit-source/magma/magma_common_device.h", &magma_common_path); CeedChkBackend(ierr); CeedDebug256(ceed, 2, "----- Loading Basis Kernel Source -----\n"); ierr = CeedLoadSourceToBuffer(ceed, magma_common_path, &basis_kernel_source); CeedChkBackend(ierr); char *interp_name_base = "ceed/jit-source/magma/interp"; CeedInt interp_name_len = strlen(interp_name_base) + 6; char interp_name[interp_name_len]; snprintf(interp_name, interp_name_len, "%s-%dd.h", interp_name_base, dim); ierr = CeedGetJitAbsolutePath(ceed, interp_name, &interp_path); CeedChkBackend(ierr); ierr = CeedLoadSourceToInitializedBuffer(ceed, interp_path, &basis_kernel_source); CeedChkBackend(ierr); char *grad_name_base = "ceed/jit-source/magma/grad"; CeedInt grad_name_len = strlen(grad_name_base) + 6; char grad_name[grad_name_len]; snprintf(grad_name, grad_name_len, "%s-%dd.h", grad_name_base, dim); ierr = CeedGetJitAbsolutePath(ceed, grad_name, &grad_path); CeedChkBackend(ierr); ierr = CeedLoadSourceToInitializedBuffer(ceed, grad_path, &basis_kernel_source); CeedChkBackend(ierr); char *weight_name_base = "ceed/jit-source/magma/weight"; CeedInt weight_name_len = strlen(weight_name_base) + 6; char weight_name[weight_name_len]; snprintf(weight_name, weight_name_len, "%s-%dd.h", weight_name_base, dim); ierr = CeedGetJitAbsolutePath(ceed, weight_name, &weight_path); CeedChkBackend(ierr); ierr = CeedLoadSourceToInitializedBuffer(ceed, weight_path, &basis_kernel_source); CeedChkBackend(ierr); CeedDebug256(ceed, 2, "----- Loading Basis Kernel Source Complete! -----\n"); // The RTC compilation code expects a Ceed with the common Ceed_Cuda or Ceed_Hip // data Ceed delegate; ierr = CeedGetDelegate(ceed, &delegate); CeedChkBackend(ierr); ierr = MAGMA_RTC_COMPILE(delegate, basis_kernel_source, &impl->module, 5, "DIM", dim, "NCOMP", ncomp, "P", P1d, "Q", Q1d, "MAXPQ", CeedIntMax(P1d, Q1d)); CeedChkBackend(ierr); // Kernel setup switch (dim) { case 1: ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_interpn_1d_kernel", &impl->magma_interp); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_interpt_1d_kernel", &impl->magma_interp_tr); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_gradn_1d_kernel", &impl->magma_grad); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_gradt_1d_kernel", &impl->magma_grad_tr); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_weight_1d_kernel", &impl->magma_weight); CeedChkBackend(ierr); break; case 2: ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_interpn_2d_kernel", &impl->magma_interp); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_interpt_2d_kernel", &impl->magma_interp_tr); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_gradn_2d_kernel", &impl->magma_grad); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_gradt_2d_kernel", &impl->magma_grad_tr); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_weight_2d_kernel", &impl->magma_weight); CeedChkBackend(ierr); break; case 3: ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_interpn_3d_kernel", &impl->magma_interp); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_interpt_3d_kernel", &impl->magma_interp_tr); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_gradn_3d_kernel", &impl->magma_grad); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_gradt_3d_kernel", &impl->magma_grad_tr); CeedChkBackend(ierr); ierr = MAGMA_RTC_GET_KERNEL(ceed, impl->module, "magma_weight_3d_kernel", &impl->magma_weight); CeedChkBackend(ierr); } ierr = CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApply_Magma); CeedChkBackend(ierr); ierr = CeedSetBackendFunction(ceed, "Basis", basis, "Destroy", CeedBasisDestroy_Magma); CeedChkBackend(ierr); // Copy qref1d to the GPU ierr = magma_malloc((void **)&impl->dqref1d, Q1d*sizeof(qref1d[0])); CeedChkBackend(ierr); magma_setvector(Q1d, sizeof(qref1d[0]), qref1d, 1, impl->dqref1d, 1, data->queue); // Copy interp1d to the GPU ierr = magma_malloc((void **)&impl->dinterp1d, Q1d*P1d*sizeof(interp1d[0])); CeedChkBackend(ierr); magma_setvector(Q1d*P1d, sizeof(interp1d[0]), interp1d, 1, impl->dinterp1d, 1, data->queue); // Copy grad1d to the GPU ierr = magma_malloc((void **)&impl->dgrad1d, Q1d*P1d*sizeof(grad1d[0])); CeedChkBackend(ierr); magma_setvector(Q1d*P1d, sizeof(grad1d[0]), grad1d, 1, impl->dgrad1d, 1, data->queue); // Copy qweight1d to the GPU ierr = magma_malloc((void **)&impl->dqweight1d, Q1d*sizeof(qweight1d[0])); CeedChkBackend(ierr); magma_setvector(Q1d, sizeof(qweight1d[0]), qweight1d, 1, impl->dqweight1d, 1, data->queue); ierr = CeedBasisSetData(basis, impl); CeedChkBackend(ierr); return CEED_ERROR_SUCCESS; } #ifdef __cplusplus CEED_INTERN "C" #endif int CeedBasisCreateH1_Magma(CeedElemTopology topo, CeedInt dim, CeedInt ndof, CeedInt nqpts, const CeedScalar *interp, const CeedScalar *grad, const CeedScalar *qref, const CeedScalar *qweight, CeedBasis basis) { int ierr; CeedBasisNonTensor_Magma *impl; Ceed ceed; ierr = CeedBasisGetCeed(basis, &ceed); CeedChkBackend(ierr); Ceed_Magma *data; ierr = CeedGetData(ceed, &data); CeedChkBackend(ierr); if (CEED_SCALAR_TYPE == CEED_SCALAR_FP64) { ierr = CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApplyNonTensor_f64_Magma); CeedChkBackend(ierr); } else { ierr = CeedSetBackendFunction(ceed, "Basis", basis, "Apply", CeedBasisApplyNonTensor_f32_Magma); CeedChkBackend(ierr); } ierr = CeedSetBackendFunction(ceed, "Basis", basis, "Destroy", CeedBasisDestroyNonTensor_Magma); CeedChkBackend(ierr); ierr = CeedCalloc(1,&impl); CeedChkBackend(ierr); ierr = CeedBasisSetData(basis, impl); CeedChkBackend(ierr); // Copy qref to the GPU ierr = magma_malloc((void **)&impl->dqref, nqpts*sizeof(qref[0])); CeedChkBackend(ierr); magma_setvector(nqpts, sizeof(qref[0]), qref, 1, impl->dqref, 1, data->queue); // Copy interp to the GPU ierr = magma_malloc((void **)&impl->dinterp, nqpts*ndof*sizeof(interp[0])); CeedChkBackend(ierr); magma_setvector(nqpts*ndof, sizeof(interp[0]), interp, 1, impl->dinterp, 1, data->queue); // Copy grad to the GPU ierr = magma_malloc((void **)&impl->dgrad, nqpts*ndof*dim*sizeof(grad[0])); CeedChkBackend(ierr); magma_setvector(nqpts*ndof*dim, sizeof(grad[0]), grad, 1, impl->dgrad, 1, data->queue); // Copy qweight to the GPU ierr = magma_malloc((void **)&impl->dqweight, nqpts*sizeof(qweight[0])); CeedChkBackend(ierr); magma_setvector(nqpts, sizeof(qweight[0]), qweight, 1, impl->dqweight, 1, data->queue); return CEED_ERROR_SUCCESS; }