crml_gpu_kernel.cu
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Created: Fri, Jun 21, 18:10

crml_gpu_kernel.cu
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	/* ----------------------------------------------------------------------
	LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator
	http://lammps.sandia.gov, Sandia National Laboratories
	Steve Plimpton, sjplimp@sandia.gov

	Copyright (2003) Sandia Corporation. Under the terms of Contract
	DE-AC04-94AL85000 with Sandia Corporation, the U.S. Government retains
	certain rights in this software. This software is distributed under
	the GNU General Public License.

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

	/* ----------------------------------------------------------------------
	Contributing authors: Mike Brown (ORNL), brownw@ornl.gov
	------------------------------------------------------------------------- */

	#ifndef CRML_GPU_KERNEL
	#define CRML_GPU_KERNEL

	#ifdef NV_KERNEL

	#include "nv_kernel_def.h"
	texture<float4> pos_tex;
	texture<float> q_tex;

	#ifdef _DOUBLE_DOUBLE
	__inline double4 fetch_pos(const int& i, const double4 *pos)
	{
	return pos[i];
	}
	__inline double fetch_q(const int& i, const double *q)
	{
	return q[i];
	}
	#else
	__inline float4 fetch_pos(const int& i, const float4 *pos)
	{
	return tex1Dfetch(pos_tex, i);
	}
	__inline float fetch_q(const int& i, const float *q)
	{
	return tex1Dfetch(q_tex, i);
	}
	#endif

	#else

	#pragma OPENCL EXTENSION cl_khr_fp64: enable
	#define GLOBAL_ID_X get_global_id(0)
	#define THREAD_ID_X get_local_id(0)
	#define BLOCK_ID_X get_group_id(0)
	#define BLOCK_SIZE_X get_local_size(0)
	#define __syncthreads() barrier(CLK_LOCAL_MEM_FENCE)
	#define __inline inline

	#define fetch_pos(i,y) x_[i]
	#define fetch_q(i,y) q_[i]
	#define BLOCK_BIO_PAIR 64

	#endif

	#define MAX_BIO_SHARED_TYPES 128

	#ifdef _DOUBLE_DOUBLE
	#define numtyp double
	#define numtyp2 double2
	#define numtyp4 double4
	#define acctyp double
	#define acctyp4 double4
	#endif

	#ifdef _SINGLE_DOUBLE
	#define numtyp float
	#define numtyp2 float2
	#define numtyp4 float4
	#define acctyp double
	#define acctyp4 double4
	#endif

	#ifndef numtyp
	#define numtyp float
	#define numtyp2 float2
	#define numtyp4 float4
	#define acctyp float
	#define acctyp4 float4
	#endif

	#define EWALD_F (numtyp)1.12837917
	#define EWALD_P (numtyp)0.3275911
	#define A1 (numtyp)0.254829592
	#define A2 (numtyp)-0.284496736
	#define A3 (numtyp)1.421413741
	#define A4 (numtyp)-1.453152027
	#define A5 (numtyp)1.061405429

	#define SBBITS 30
	#define NEIGHMASK 0x3FFFFFFF
	__inline int sbmask(int j) { return j >> SBBITS & 3; }

	__kernel void kernel_pair(__global numtyp4 x_, __global numtyp4 lj1,
	const int lj_types, __global numtyp *sp_lj_in,
	__global int dev_nbor, __global int dev_packed,
	__global acctyp4 ans, __global acctyp engv,
	const int eflag, const int vflag, const int inum,
	const int nbor_pitch, __global numtyp *q_,
	const numtyp cut_coulsq, const numtyp qqrd2e,
	const numtyp g_ewald, const numtyp denom_lj,
	const numtyp cut_bothsq, const numtyp cut_ljsq,
	const numtyp cut_lj_innersq, const int t_per_atom) {

	int tid=THREAD_ID_X;
	int ii=mul24((int)BLOCK_ID_X,(int)(BLOCK_SIZE_X)/t_per_atom);
	ii+=tid/t_per_atom;
	int offset=tid%t_per_atom;

	__local numtyp sp_lj[8];
	sp_lj[0]=sp_lj_in[0];
	sp_lj[1]=sp_lj_in[1];
	sp_lj[2]=sp_lj_in[2];
	sp_lj[3]=sp_lj_in[3];
	sp_lj[4]=sp_lj_in[4];
	sp_lj[5]=sp_lj_in[5];
	sp_lj[6]=sp_lj_in[6];
	sp_lj[7]=sp_lj_in[7];

	acctyp energy=(acctyp)0;
	acctyp e_coul=(acctyp)0;
	acctyp4 f;
	f.x=(acctyp)0;
	f.y=(acctyp)0;
	f.z=(acctyp)0;
	acctyp virial[6];
	for (int i=0; i<6; i++)
	virial[i]=(acctyp)0;

	if (ii<inum) {
	__global int *nbor=dev_nbor+ii;
	int i=*nbor;
	nbor+=nbor_pitch;
	int numj=*nbor;
	nbor+=nbor_pitch;

	int n_stride;
	__global int *list_end;
	if (dev_nbor==dev_packed) {
	list_end=nbor+mul24(numj,nbor_pitch);
	nbor+=mul24(offset,nbor_pitch);
	n_stride=mul24(t_per_atom,nbor_pitch);
	} else {
	nbor=dev_packed+*nbor;
	list_end=nbor+numj;
	n_stride=t_per_atom;
	nbor+=offset;
	}

	numtyp4 ix=fetch_pos(i,x_); //x_[i];
	numtyp qtmp=fetch_q(i,q_);
	int itype=ix.w;

	for ( ; nbor<list_end; nbor+=n_stride) {
	int j=*nbor;

	numtyp factor_lj, factor_coul;
	factor_lj = sp_lj[sbmask(j)];
	factor_coul = (numtyp)1.0-sp_lj[sbmask(j)+4];
	j &= NEIGHMASK;

	numtyp4 jx=fetch_pos(j,x_); //x_[j];
	int jtype=jx.w;

	// Compute r12
	numtyp delx = ix.x-jx.x;
	numtyp dely = ix.y-jx.y;
	numtyp delz = ix.z-jx.z;
	numtyp rsq = delxdelx+delydely+delz*delz;

	int mtype=itype*lj_types+jtype;
	if (rsq<cut_bothsq) {
	numtyp r2inv=(numtyp)1.0/rsq;
	numtyp forcecoul, force_lj, force, r6inv, prefactor, _erfc, switch1;

	if (rsq < cut_ljsq) {
	r6inv = r2invr2invr2inv;
	force_lj = factor_ljr6inv(lj1[mtype].x*r6inv-lj1[mtype].y);
	if (rsq > cut_lj_innersq) {
	switch1 = (cut_ljsq-rsq);
	numtyp switch2 = (numtyp)12.0rsqswitch1*(rsq-cut_lj_innersq)/
	denom_lj;
	switch1 *= switch1;
	switch1 = (cut_ljsq+(numtyp)2.0rsq-(numtyp)3.0*cut_lj_innersq)/
	denom_lj;
	switch2 = r6inv(lj1[mtype].z*r6inv-lj1[mtype].w);
	force_lj = force_lj*switch1+switch2;
	}
	} else
	force_lj = (numtyp)0.0;

	if (rsq < cut_coulsq) {
	numtyp r = sqrt(rsq);
	numtyp grij = g_ewald * r;
	numtyp expm2 = exp(-grij*grij);
	numtyp t = (numtyp)1.0 / ((numtyp)1.0 + EWALD_P*grij);
	_erfc = t * (A1+t(A2+t(A3+t(A4+tA5)))) * expm2;
	prefactor = qqrd2e * qtmp*fetch_q(j,q_)/r;
	forcecoul = prefactor * (_erfc + EWALD_Fgrijexpm2-factor_coul);
	} else {
	forcecoul = (numtyp)0.0;
	prefactor = (numtyp)0.0;
	}

	force = (force_lj + forcecoul) * r2inv;

	f.x+=delx*force;
	f.y+=dely*force;
	f.z+=delz*force;

	if (eflag>0) {
	e_coul += prefactor*(_erfc-factor_coul);
	if (rsq < cut_ljsq) {
	numtyp e=r6inv(lj1[mtype].zr6inv-lj1[mtype].w);
	if (rsq > cut_lj_innersq)
	e *= switch1;
	energy+=factor_lj*e;
	}
	}
	if (vflag>0) {
	virial[0] += delxdelxforce;
	virial[1] += delydelyforce;
	virial[2] += delzdelzforce;
	virial[3] += delxdelyforce;
	virial[4] += delxdelzforce;
	virial[5] += delydelzforce;
	}
	}

	} // for nbor
	} // if ii

	// Reduce answers
	if (t_per_atom>1) {
	__local acctyp red_acc[6][BLOCK_BIO_PAIR];

	red_acc[0][tid]=f.x;
	red_acc[1][tid]=f.y;
	red_acc[2][tid]=f.z;
	red_acc[3][tid]=energy;
	red_acc[4][tid]=e_coul;

	for (unsigned int s=t_per_atom/2; s>0; s>>=1) {
	if (offset < s) {
	for (int r=0; r<5; r++)
	red_acc[r][tid] += red_acc[r][tid+s];
	}
	}

	f.x=red_acc[0][tid];
	f.y=red_acc[1][tid];
	f.z=red_acc[2][tid];
	energy=red_acc[3][tid];
	e_coul=red_acc[4][tid];

	if (vflag>0) {
	for (int r=0; r<6; r++)
	red_acc[r][tid]=virial[r];

	for (unsigned int s=t_per_atom/2; s>0; s>>=1) {
	if (offset < s) {
	for (int r=0; r<6; r++)
	red_acc[r][tid] += red_acc[r][tid+s];
	}
	}

	for (int r=0; r<6; r++)
	virial[r]=red_acc[r][tid];
	}
	}

	// Store answers
	if (ii<inum && offset==0) {
	__global acctyp *ap1=engv+ii;
	if (eflag>0) {
	*ap1=energy;
	ap1+=inum;
	*ap1=e_coul;
	ap1+=inum;
	}
	if (vflag>0) {
	for (int i=0; i<6; i++) {
	*ap1=virial[i];
	ap1+=inum;
	}
	}
	ans[ii]=f;
	} // if ii
	}

	__kernel void kernel_pair_fast(__global numtyp4 x_, __global numtyp2 ljd_in,
	__global numtyp* sp_lj_in, __global int *dev_nbor,
	__global int dev_packed, __global acctyp4 ans,
	__global acctyp *engv, const int eflag,
	const int vflag, const int inum,
	const int nbor_pitch, __global numtyp *q_,
	const numtyp cut_coulsq, const numtyp qqrd2e,
	const numtyp g_ewald, const numtyp denom_lj,
	const numtyp cut_bothsq, const numtyp cut_ljsq,
	const numtyp cut_lj_innersq,
	const int t_per_atom) {
	int tid=THREAD_ID_X;
	int ii=mul24((int)BLOCK_ID_X,(int)(BLOCK_SIZE_X)/t_per_atom);
	ii+=tid/t_per_atom;
	int offset=tid%t_per_atom;

	__local numtyp2 ljd[MAX_BIO_SHARED_TYPES];
	__local numtyp sp_lj[8];
	if (tid<8)
	sp_lj[tid]=sp_lj_in[tid];
	ljd[tid]=ljd_in[tid];
	if (tid+BLOCK_BIO_PAIR<MAX_BIO_SHARED_TYPES)
	ljd[tid+BLOCK_BIO_PAIR]=ljd_in[tid+BLOCK_BIO_PAIR];

	acctyp energy=(acctyp)0;
	acctyp e_coul=(acctyp)0;
	acctyp4 f;
	f.x=(acctyp)0;
	f.y=(acctyp)0;
	f.z=(acctyp)0;
	acctyp virial[6];
	for (int i=0; i<6; i++)
	virial[i]=(acctyp)0;

	__syncthreads();

	if (ii<inum) {
	__global int *nbor=dev_nbor+ii;
	int i=*nbor;
	nbor+=nbor_pitch;
	int numj=*nbor;
	nbor+=nbor_pitch;

	int n_stride;
	__global int *list_end;
	if (dev_nbor==dev_packed) {
	list_end=nbor+mul24(numj,nbor_pitch);
	nbor+=mul24(offset,nbor_pitch);
	n_stride=mul24(t_per_atom,nbor_pitch);
	} else {
	nbor=dev_packed+*nbor;
	list_end=nbor+numj;
	n_stride=t_per_atom;
	nbor+=offset;
	}

	numtyp4 ix=fetch_pos(i,x_); //x_[i];
	numtyp qtmp=fetch_q(i,q_);
	int itype=ix.w;

	for ( ; nbor<list_end; nbor+=n_stride) {
	int j=*nbor;

	numtyp factor_lj, factor_coul;
	factor_lj = sp_lj[sbmask(j)];
	factor_coul = (numtyp)1.0-sp_lj[sbmask(j)+4];
	j &= NEIGHMASK;

	numtyp4 jx=fetch_pos(j,x_); //x_[j];
	int jtype=jx.w;

	// Compute r12
	numtyp delx = ix.x-jx.x;
	numtyp dely = ix.y-jx.y;
	numtyp delz = ix.z-jx.z;
	numtyp rsq = delxdelx+delydely+delz*delz;

	if (rsq<cut_bothsq) {
	numtyp r2inv=(numtyp)1.0/rsq;
	numtyp forcecoul, force_lj, force, prefactor, _erfc, switch1;
	numtyp lj3, lj4;

	if (rsq < cut_ljsq) {
	numtyp eps = sqrt(ljd[itype].x*ljd[jtype].x);
	numtyp sig6 = (numtyp)0.5 * (ljd[itype].y+ljd[jtype].y);

	numtyp sig_r_6 = sig6sig6r2inv;
	sig_r_6 = sig_r_6sig_r_6sig_r_6;
	lj4 = (numtyp)4.0epssig_r_6;
	lj3 = lj4*sig_r_6;
	force_lj = factor_lj((numtyp)12.0 lj3 - (numtyp)6.0 * lj4);
	if (rsq > cut_lj_innersq) {
	switch1 = (cut_ljsq-rsq);
	numtyp switch2 = (numtyp)12.0rsqswitch1*(rsq-cut_lj_innersq)/
	denom_lj;
	switch1 *= switch1;
	switch1 = (cut_ljsq+(numtyp)2.0rsq-(numtyp)3.0*cut_lj_innersq)/
	denom_lj;
	switch2 *= lj3-lj4;
	force_lj = force_lj*switch1+switch2;
	}
	} else
	force_lj = (numtyp)0.0;

	if (rsq < cut_coulsq) {
	numtyp r = sqrt(rsq);
	numtyp grij = g_ewald * r;
	numtyp expm2 = exp(-grij*grij);
	numtyp t = (numtyp)1.0 / ((numtyp)1.0 + EWALD_P*grij);
	_erfc = t * (A1+t(A2+t(A3+t(A4+tA5)))) * expm2;
	prefactor = qqrd2e * qtmp*fetch_q(j,q_)/r;
	forcecoul = prefactor * (_erfc + EWALD_Fgrijexpm2-factor_coul);
	} else {
	forcecoul = (numtyp)0.0;
	prefactor = (numtyp)0.0;
	}

	force = (force_lj + forcecoul) * r2inv;

	f.x+=delx*force;
	f.y+=dely*force;
	f.z+=delz*force;

	if (eflag>0) {
	e_coul += prefactor*(_erfc-factor_coul);
	if (rsq < cut_ljsq) {
	numtyp e=lj3-lj4;
	if (rsq > cut_lj_innersq)
	e *= switch1;
	energy+=factor_lj*e;
	}
	}
	if (vflag>0) {
	virial[0] += delxdelxforce;
	virial[1] += delydelyforce;
	virial[2] += delzdelzforce;
	virial[3] += delxdelyforce;
	virial[4] += delxdelzforce;
	virial[5] += delydelzforce;
	}
	}

	} // for nbor
	} // if ii

	// Reduce answers
	if (t_per_atom>1) {
	__local acctyp red_acc[6][BLOCK_BIO_PAIR];

	red_acc[0][tid]=f.x;
	red_acc[1][tid]=f.y;
	red_acc[2][tid]=f.z;
	red_acc[3][tid]=energy;
	red_acc[4][tid]=e_coul;

	for (unsigned int s=t_per_atom/2; s>0; s>>=1) {
	if (offset < s) {
	for (int r=0; r<5; r++)
	red_acc[r][tid] += red_acc[r][tid+s];
	}
	}

	f.x=red_acc[0][tid];
	f.y=red_acc[1][tid];
	f.z=red_acc[2][tid];
	energy=red_acc[3][tid];
	e_coul=red_acc[4][tid];

	if (vflag>0) {
	for (int r=0; r<6; r++)
	red_acc[r][tid]=virial[r];

	for (unsigned int s=t_per_atom/2; s>0; s>>=1) {
	if (offset < s) {
	for (int r=0; r<6; r++)
	red_acc[r][tid] += red_acc[r][tid+s];
	}
	}

	for (int r=0; r<6; r++)
	virial[r]=red_acc[r][tid];
	}
	}

	// Store answers
	if (ii<inum && offset==0) {
	__global acctyp *ap1=engv+ii;
	if (eflag>0) {
	*ap1=energy;
	ap1+=inum;
	*ap1=e_coul;
	ap1+=inum;
	}
	if (vflag>0) {
	for (int i=0; i<6; i++) {
	*ap1=virial[i];
	ap1+=inum;
	}
	}
	ans[ii]=f;
	} // if ii
	}

	#endif

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