/* * Copyright (C) NHR@FAU, University Erlangen-Nuremberg. * All rights reserved. This file is part of MD-Bench. * Use of this source code is governed by a LGPL-3.0 * license that can be found in the LICENSE file. */ #include #ifndef __ATOM_H_ #define __ATOM_H_ #define DELTA 20000 // Nbnxn layouts (as of GROMACS): // Simd4xN: M=4, N=VECTOR_WIDTH // Simd2xNN: M=4, N=(VECTOR_WIDTH/2) // Cuda: M=8, N=VECTOR_WIDTH #ifdef CUDA_TARGET # undef VECTOR_WIDTH # define VECTOR_WIDTH 8 # define KERNEL_NAME "CUDA" # define CLUSTER_M 8 # define CLUSTER_N VECTOR_WIDTH # define UNROLL_J 1 # define computeForceLJ computeForceLJ_cuda # define initialIntegrate cudaInitialIntegrate # define finalIntegrate cudaFinalIntegrate # define updatePbc cudaUpdatePbc #else # define CLUSTER_M 4 // Simd2xNN (here used for single-precision) # if VECTOR_WIDTH > CLUSTER_M * 2 # define KERNEL_NAME "Simd2xNN" # define CLUSTER_N (VECTOR_WIDTH / 2) # define UNROLL_I 4 # define UNROLL_J 2 # define computeForceLJ computeForceLJ_2xnn // Simd4xN # else # define KERNEL_NAME "Simd4xN" # define CLUSTER_N VECTOR_WIDTH # define UNROLL_I 4 # define UNROLL_J 1 # define computeForceLJ computeForceLJ_4xn # endif # ifdef USE_REFERENCE_VERSION # undef KERNEL_NAME # undef computeForceLJ # define KERNEL_NAME "Reference" # define computeForceLJ computeForceLJ_ref # endif # define initialIntegrate cpuInitialIntegrate # define finalIntegrate cpuFinalIntegrate # define updatePbc cpuUpdatePbc #endif #if CLUSTER_M == CLUSTER_N # define CJ0_FROM_CI(a) (a) # define CJ1_FROM_CI(a) (a) # define CI_BASE_INDEX(a,b) ((a) * CLUSTER_N * (b)) # define CJ_BASE_INDEX(a,b) ((a) * CLUSTER_N * (b)) #elif CLUSTER_M == CLUSTER_N * 2 // M > N # define CJ0_FROM_CI(a) ((a) << 1) # define CJ1_FROM_CI(a) (((a) << 1) | 0x1) # define CI_BASE_INDEX(a,b) ((a) * CLUSTER_M * (b)) # define CJ_BASE_INDEX(a,b) (((a) >> 1) * CLUSTER_M * (b) + ((a) & 0x1) * (CLUSTER_M >> 1)) #elif CLUSTER_M == CLUSTER_N / 2 // M < N # define CJ0_FROM_CI(a) ((a) >> 1) # define CJ1_FROM_CI(a) ((a) >> 1) # define CI_BASE_INDEX(a,b) (((a) >> 1) * CLUSTER_N * (b) + ((a) & 0x1) * (CLUSTER_N >> 1)) # define CJ_BASE_INDEX(a,b) ((a) * CLUSTER_N * (b)) #else # error "Invalid cluster configuration!" #endif #if CLUSTER_N != 2 && CLUSTER_N != 4 && CLUSTER_N != 8 # error "Cluster N dimension can be only 2, 4 and 8" #endif #define CI_SCALAR_BASE_INDEX(a) (CI_BASE_INDEX(a, 1)) #define CI_VECTOR_BASE_INDEX(a) (CI_BASE_INDEX(a, 3)) #define CJ_SCALAR_BASE_INDEX(a) (CJ_BASE_INDEX(a, 1)) #define CJ_VECTOR_BASE_INDEX(a) (CJ_BASE_INDEX(a, 3)) #if CLUSTER_M >= CLUSTER_N # define CL_X_OFFSET (0 * CLUSTER_M) # define CL_Y_OFFSET (1 * CLUSTER_M) # define CL_Z_OFFSET (2 * CLUSTER_M) #else # define CL_X_OFFSET (0 * CLUSTER_N) # define CL_Y_OFFSET (1 * CLUSTER_N) # define CL_Z_OFFSET (2 * CLUSTER_N) #endif typedef struct { int natoms; MD_FLOAT bbminx, bbmaxx; MD_FLOAT bbminy, bbmaxy; MD_FLOAT bbminz, bbmaxz; } Cluster; typedef struct { int Natoms, Nlocal, Nghost, Nmax; int Nclusters, Nclusters_local, Nclusters_ghost, Nclusters_max; MD_FLOAT *x, *y, *z; MD_FLOAT *vx, *vy, *vz; int *border_map; int *type; int ntypes; MD_FLOAT *epsilon; MD_FLOAT *sigma6; MD_FLOAT *cutforcesq; MD_FLOAT *cutneighsq; int *PBCx, *PBCy, *PBCz; // Data in cluster format MD_FLOAT *cl_x; MD_FLOAT *cl_v; MD_FLOAT *cl_f; int *cl_type; Cluster *iclusters, *jclusters; int *icluster_bin; int dummy_cj; MD_UINT *exclusion_filter; MD_FLOAT *diagonal_4xn_j_minus_i; MD_FLOAT *diagonal_2xnn_j_minus_i; unsigned int masks_2xnn_hn[8]; unsigned int masks_2xnn_fn[8]; unsigned int masks_4xn_hn[16]; unsigned int masks_4xn_fn[16]; } Atom; extern void initAtom(Atom*); extern void initMasks(Atom*); extern void createAtom(Atom*, Parameter*); extern int readAtom(Atom*, Parameter*); extern int readAtom_pdb(Atom*, Parameter*); extern int readAtom_gro(Atom*, Parameter*); extern int readAtom_dmp(Atom*, Parameter*); extern void growAtom(Atom*); extern void growClusters(Atom*); #ifdef AOS # define POS_DATA_LAYOUT "AoS" # define atom_x(i) atom->x[(i) * 3 + 0] # define atom_y(i) atom->x[(i) * 3 + 1] # define atom_z(i) atom->x[(i) * 3 + 2] /* # define atom_vx(i) atom->vx[(i) * 3 + 0] # define atom_vy(i) atom->vx[(i) * 3 + 1] # define atom_vz(i) atom->vx[(i) * 3 + 2] # define atom_fx(i) atom->fx[(i) * 3 + 0] # define atom_fy(i) atom->fx[(i) * 3 + 1] # define atom_fz(i) atom->fx[(i) * 3 + 2] */ #else # define POS_DATA_LAYOUT "SoA" # define atom_x(i) atom->x[i] # define atom_y(i) atom->y[i] # define atom_z(i) atom->z[i] #endif // TODO: allow to switch velocites and forces to AoS # define atom_vx(i) atom->vx[i] # define atom_vy(i) atom->vy[i] # define atom_vz(i) atom->vz[i] # define atom_fx(i) atom->fx[i] # define atom_fy(i) atom->fy[i] # define atom_fz(i) atom->fz[i] #endif