// 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 /// @file /// Internal header for HIP shared memory non-tensor basis #include #include "hip-shared-basis-nontensor-templates.h" #include "hip-shared-basis-read-write-templates.h" //------------------------------------------------------------------------------ // Interp kernels //------------------------------------------------------------------------------ extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void Interp(const CeedInt num_elem, const CeedScalar *c_B, const CeedScalar *__restrict__ d_U, CeedScalar *__restrict__ d_V) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_U[BASIS_NUM_COMP]; CeedScalar r_V[BASIS_NUM_COMP]; // load interp into shared memory __shared__ CeedScalar s_B[BASIS_P * BASIS_Q]; LoadMatrix(data, c_B, s_B); __syncthreads(); // Apply basis element by element for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { ReadElementStrided1d(data, elem, 1, BASIS_P * num_elem, BASIS_P, d_U, r_U); InterpNonTensor(data, r_U, s_B, r_V); WriteElementStrided1d(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, r_V, d_V); } } extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void InterpTranspose(const CeedInt num_elem, const CeedScalar *c_B, const CeedScalar *__restrict__ d_U, CeedScalar *__restrict__ d_V) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_U[BASIS_NUM_COMP]; CeedScalar r_V[BASIS_NUM_COMP]; // load interp into shared memory __shared__ CeedScalar s_B[BASIS_P * BASIS_Q]; LoadMatrix(data, c_B, s_B); __syncthreads(); // Apply basis element by element for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { ReadElementStrided1d(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, d_U, r_U); InterpTransposeNonTensor(data, r_U, s_B, r_V); WriteElementStrided1d(data, elem, 1, BASIS_P * num_elem, BASIS_P, r_V, d_V); } } extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void InterpTransposeAdd(const CeedInt num_elem, const CeedScalar *c_B, const CeedScalar *__restrict__ d_U, CeedScalar *__restrict__ d_V) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_U[BASIS_NUM_COMP]; CeedScalar r_V[BASIS_NUM_COMP]; // load interp into shared memory __shared__ CeedScalar s_B[BASIS_P * BASIS_Q]; LoadMatrix(data, c_B, s_B); __syncthreads(); // Apply basis element by element for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { ReadElementStrided1d(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, d_U, r_U); InterpTransposeNonTensor(data, r_U, s_B, r_V); SumElementStrided1d(data, elem, 1, BASIS_P * num_elem, BASIS_P, r_V, d_V); } } //------------------------------------------------------------------------------ // Grad kernels //------------------------------------------------------------------------------ extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void Grad(const CeedInt num_elem, const CeedScalar *c_G, const CeedScalar *__restrict__ d_U, CeedScalar *__restrict__ d_V) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_U[BASIS_NUM_COMP]; CeedScalar r_V[BASIS_NUM_COMP * BASIS_DIM]; // load grad into shared memory __shared__ CeedScalar s_G[BASIS_P * BASIS_Q * BASIS_DIM]; LoadMatrix(data, c_G, s_G); __syncthreads(); // Apply basis element by element for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { ReadElementStrided1d(data, elem, 1, BASIS_P * num_elem, BASIS_P, d_U, r_U); GradNonTensor(data, r_U, s_G, r_V); WriteElementStrided1d(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, r_V, d_V); } } extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void GradTranspose(const CeedInt num_elem, const CeedScalar *c_G, const CeedScalar *__restrict__ d_U, CeedScalar *__restrict__ d_V) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_U[BASIS_NUM_COMP * BASIS_DIM]; CeedScalar r_V[BASIS_NUM_COMP]; // load grad into shared memory __shared__ CeedScalar s_G[BASIS_P * BASIS_Q * BASIS_DIM]; LoadMatrix(data, c_G, s_G); __syncthreads(); // Apply basis element by element for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { ReadElementStrided1d(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, d_U, r_U); GradTransposeNonTensor(data, r_U, s_G, r_V); WriteElementStrided1d(data, elem, 1, BASIS_P * num_elem, BASIS_P, r_V, d_V); } } extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void GradTransposeAdd(const CeedInt num_elem, const CeedScalar *c_G, const CeedScalar *__restrict__ d_U, CeedScalar *__restrict__ d_V) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_U[BASIS_NUM_COMP * BASIS_DIM]; CeedScalar r_V[BASIS_NUM_COMP]; // load grad into shared memory __shared__ CeedScalar s_G[BASIS_P * BASIS_Q * BASIS_DIM]; LoadMatrix(data, c_G, s_G); __syncthreads(); // Apply basis element by element for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { ReadElementStrided1d(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, d_U, r_U); GradTransposeNonTensor(data, r_U, s_G, r_V); SumElementStrided1d(data, elem, 1, BASIS_P * num_elem, BASIS_P, r_V, d_V); } } //------------------------------------------------------------------------------ // Weight kernel //------------------------------------------------------------------------------ extern "C" __launch_bounds__(BASIS_INTERP_BLOCK_SIZE) __global__ void Weight(const CeedInt num_elem, const CeedScalar *__restrict__ q_weight, CeedScalar *__restrict__ d_W) { extern __shared__ CeedScalar slice[]; SharedData_Hip data; data.t_id_x = threadIdx.x; data.t_id_y = threadIdx.y; data.t_id_z = threadIdx.z; data.t_id = threadIdx.x + threadIdx.y * blockDim.x + threadIdx.z * blockDim.y * blockDim.x; data.slice = slice + data.t_id_z * BASIS_T_1D; CeedScalar r_W[1]; for (CeedInt elem = blockIdx.x * blockDim.z + threadIdx.z; elem < num_elem; elem += gridDim.x * blockDim.z) { WeightNonTensor(data, q_weight, r_W); WriteElementStrided1d<1, BASIS_Q>(data, elem, 1, BASIS_Q * num_elem, BASIS_Q, r_W, d_W); } }