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Created: Wed, Oct 9, 13:42

pair_sw_cuda.cu
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	/* ----------------------------------------------------------------------
	LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator

	Original Version:
	http://lammps.sandia.gov, Sandia National Laboratories
	Steve Plimpton, sjplimp@sandia.gov

	See the README file in the top-level LAMMPS directory.

	-----------------------------------------------------------------------

	USER-CUDA Package and associated modifications:
	https://sourceforge.net/projects/lammpscuda/

	Christian Trott, christian.trott@tu-ilmenau.de
	Lars Winterfeld, lars.winterfeld@tu-ilmenau.de
	Theoretical Physics II, University of Technology Ilmenau, Germany

	See the README file in the USER-CUDA directory.

	This software is distributed under the GNU General Public License.
	------------------------------------------------------------------------- */

	#include <stdio.h>

	#include "pair_sw_cuda_cu.h"
	__device__ __constant__ ParamSW_Float params_sw[MANYBODY_NPAIR* MANYBODY_NPAIR* MANYBODY_NPAIR];

	#include "pair_sw_cuda_kernel_nc.cu"

	#include <time.h>


	void Cuda_PairSWCuda_Init(cuda_shared_data* sdata, ParamSW_Float* params_host, void* map_host, void* elem2param_host, int nelements_h)
	{
	unsigned cuda_ntypes = sdata->atom.ntypes + 1;
	X_FLOAT box_size[3] = {
	sdata->domain.subhi[0] - sdata->domain.sublo[0],
	sdata->domain.subhi[1] - sdata->domain.sublo[1],
	sdata->domain.subhi[2] - sdata->domain.sublo[2]
	};

	cudaMemcpyToSymbol(MY_AP(box_size) , box_size , sizeof(X_FLOAT) * 3);
	cudaMemcpyToSymbol(MY_AP(cuda_ntypes) , &cuda_ntypes , sizeof(unsigned));
	cudaMemcpyToSymbol(MY_AP(virial) , &sdata->pair.virial.dev_data , sizeof(ENERGY_FLOAT*));
	cudaMemcpyToSymbol(MY_AP(eng_vdwl) , &sdata->pair.eng_vdwl.dev_data , sizeof(ENERGY_FLOAT*));
	cudaMemcpyToSymbol(MY_AP(periodicity) , sdata->domain.periodicity , sizeof(int) * 3);
	cudaMemcpyToSymbol(MY_AP(collect_forces_later), &sdata->pair.collect_forces_later , sizeof(int));
	cudaMemcpyToSymbol(params_sw, params_host , sizeof(ParamSW_Float)nelements_h nelements_h * nelements_h);
	cudaMemcpyToSymbol(elem2param, elem2param_host , sizeof(int)nelements_h nelements_h * nelements_h);
	cudaMemcpyToSymbol(map, map_host , sizeof(int)*cuda_ntypes);
	cudaMemcpyToSymbol(nelements, &nelements_h, sizeof(int));
	}

	void Cuda_PairSWCuda(cuda_shared_data* sdata, cuda_shared_neighlist* sneighlist, int eflag, int vflag, int eflag_atom, int vflag_atom)
	{
	static int glob_ij_size = 0;
	static F_FLOAT4* glob_r_ij = NULL;
	static int* glob_numneigh_red = NULL;
	static int* glob_neighbors_red = NULL;
	static int* glob_neightype_red = NULL;

	if(glob_ij_size < sdata->atom.nall * sneighlist->maxneighbors * sizeof(F_FLOAT)) {
	glob_ij_size = sdata->atom.nall * sneighlist->maxneighbors * sizeof(F_FLOAT);
	cudaFree(glob_r_ij);
	cudaFree(glob_numneigh_red);
	cudaFree(glob_neighbors_red);
	cudaFree(glob_neightype_red);
	cudaMalloc(&glob_r_ij, glob_ij_size * 4);
	cudaMalloc(&glob_numneigh_red, sdata->atom.nall * sizeof(int));
	cudaMalloc(&glob_neighbors_red, sdata->atom.nall * sneighlist->maxneighbors * sizeof(int));
	cudaMalloc(&glob_neightype_red, sdata->atom.nall * sneighlist->maxneighbors * sizeof(int));
	cudaMemcpyToSymbol(_glob_numneigh_red, &glob_numneigh_red , sizeof(int*));
	cudaMemcpyToSymbol(_glob_neighbors_red, &glob_neighbors_red , sizeof(int*));
	cudaMemcpyToSymbol(_glob_neightype_red, &glob_neightype_red , sizeof(int*));
	cudaMemcpyToSymbol(_glob_r_ij, &glob_r_ij , sizeof(F_FLOAT4*));
	}

	dim3 grid, threads;
	int sharedperproc;

	Cuda_Pair_PreKernel_AllStyles(sdata, sneighlist, eflag, vflag, grid, threads, sharedperproc, false, 64);
	cudaStream_t* streams = (cudaStream_t*) CudaWrapper_returnStreams();



	dim3 grid2;

	if(sdata->atom.nall <= 256 * 64000) {
	grid2.x = (sdata->atom.nall + 255) / 256;
	grid2.y = 1;
	} else {
	grid2.x = (sdata->atom.nall + 256 * 128 - 1) / (256 * 128);
	grid2.y = 128;
	}

	grid2.z = 1;
	dim3 threads2;
	threads2.x = 256;
	threads2.y = 1;
	threads2.z = 1;

	timespec time1, time2;

	//pre-calculate all neighbordistances and zeta_ij
	clock_gettime(CLOCK_REALTIME, &time1);
	Pair_SW_Kernel_TpA_RIJ <<< grid2, threads2, 0, streams[1]>>>();
	cudaThreadSynchronize();
	clock_gettime(CLOCK_REALTIME, &time2);
	sdata->cuda_timings.test1 +=
	time2.tv_sec - time1.tv_sec + 1.0 * (time2.tv_nsec - time1.tv_nsec) / 1000000000;
	clock_gettime(CLOCK_REALTIME, &time1);

	//actual force calculation
	unsigned int sharedsize = (sharedperproc * sizeof(ENERGY_FLOAT) + 4 * sizeof(F_FLOAT)) * threads.x; //extra 4 floats per thread used to reduce register pressure

	if(eflag) {
	if(vflag)
	Pair_SW_Kernel_TpA<1, 1> <<< grid, threads, sharedsize, streams[1]>>>
	(eflag_atom, vflag_atom);
	else
	Pair_SW_Kernel_TpA<1, 0> <<< grid, threads, sharedsize, streams[1]>>>
	(eflag_atom, vflag_atom);
	} else {
	if(vflag)
	Pair_SW_Kernel_TpA<0, 1> <<< grid, threads, sharedsize, streams[1]>>>
	(eflag_atom, vflag_atom);
	else
	Pair_SW_Kernel_TpA<0, 0> <<< grid, threads, sharedsize, streams[1]>>>
	(eflag_atom, vflag_atom);
	}
	cudaThreadSynchronize();
	clock_gettime(CLOCK_REALTIME, &time2);
	sdata->cuda_timings.test2 +=
	time2.tv_sec - time1.tv_sec + 1.0 * (time2.tv_nsec - time1.tv_nsec) / 1000000000;

	Cuda_Pair_PostKernel_AllStyles(sdata, grid, sharedperproc, eflag, vflag);
	}

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