// **************************************************************************
//                               charmm_long.cu
//                             -------------------
//                           W. Michael Brown (ORNL)
//
//  Device code for acceleration of the charmm/coul/long pair style
//
// __________________________________________________________________________
//    This file is part of the LAMMPS Accelerator Library (LAMMPS_AL)
// __________________________________________________________________________
//
//    begin                :
//    email                : brownw@ornl.gov
// ***************************************************************************/

#ifdef NV_KERNEL

#include "lal_aux_fun1.h"
#ifndef _DOUBLE_DOUBLE
texture<float4> pos_tex;
texture<float> q_tex;
#else
texture<int4,1> pos_tex;
texture<int2> q_tex;
#endif

#else
#define pos_tex x_
#define q_tex q_
#endif

__kernel void k_charmm_long(const __global numtyp4 *restrict x_,
                            const __global numtyp4 *restrict lj1,
                            const int lj_types,
                            const __global numtyp *restrict sp_lj,
                            const __global int *dev_nbor,
                            const __global int *dev_packed,
                            __global acctyp4 *restrict ans,
                            __global acctyp *restrict engv,
                            const int eflag, const int vflag, const int inum,
                            const int nbor_pitch,
                            const __global numtyp *restrict 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, ii, offset;
  atom_info(t_per_atom,ii,tid,offset);

  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) {
    int nbor, nbor_end;
    int i, numj;
    __local int n_stride;
    nbor_info(dev_nbor,dev_packed,nbor_pitch,t_per_atom,ii,offset,i,numj,
              n_stride,nbor_end,nbor);

    numtyp4 ix; fetch4(ix,i,pos_tex); //x_[i];
    numtyp qtmp; fetch(qtmp,i,q_tex);
    int itype=ix.w;

    for ( ; nbor<nbor_end; nbor+=n_stride) {
      int j=dev_packed[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; fetch4(jx,j,pos_tex); //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 = delx*delx+dely*dely+delz*delz;

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

        if (rsq < cut_ljsq) {
          r6inv = r2inv*r2inv*r2inv;
          force_lj = factor_lj*r6inv*(lj1[mtype].x*r6inv-lj1[mtype].y);
          if (rsq > cut_lj_innersq) {
            switch1 = (cut_ljsq-rsq);
            numtyp switch2 = (numtyp)12.0*rsq*switch1*(rsq-cut_lj_innersq)/
                             denom_lj;
            switch1 *= switch1;
            switch1 *= (cut_ljsq+(numtyp)2.0*rsq-(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 = ucl_rsqrt(r2inv);
          numtyp grij = g_ewald * r;
          numtyp expm2 = ucl_exp(-grij*grij);
          numtyp t = ucl_recip((numtyp)1.0 + EWALD_P*grij);
          _erfc = t * (A1+t*(A2+t*(A3+t*(A4+t*A5)))) * expm2;
          fetch(prefactor,j,q_tex);
          prefactor *= qqrd2e * qtmp/r;
          forcecoul = prefactor * (_erfc + EWALD_F*grij*expm2-factor_coul);
        } else
          forcecoul = (numtyp)0.0;

        force = (force_lj + forcecoul) * r2inv;

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

        if (eflag>0) {
          if (rsq < cut_coulsq)
            e_coul += prefactor*(_erfc-factor_coul);
          if (rsq < cut_ljsq) {
            numtyp e=r6inv*(lj1[mtype].z*r6inv-lj1[mtype].w);
            if (rsq > cut_lj_innersq)
              e *= switch1;
            energy+=factor_lj*e;
          }
        }
        if (vflag>0) {
          virial[0] += delx*delx*force;
          virial[1] += dely*dely*force;
          virial[2] += delz*delz*force;
          virial[3] += delx*dely*force;
          virial[4] += delx*delz*force;
          virial[5] += dely*delz*force;
        }
      }

    } // for nbor
    store_answers_q(f,energy,e_coul,virial,ii,inum,tid,t_per_atom,offset,eflag,
                    vflag,ans,engv);
  } // if ii
}

__kernel void k_charmm_long_fast(const __global numtyp4 *restrict x_,
                                 const __global numtyp2 *restrict ljd_in,
                                 const __global numtyp *restrict sp_lj_in,
                                 const __global int *dev_nbor,
                                 const __global int *dev_packed,
                                 __global acctyp4 *restrict ans,
                                 __global acctyp *restrict engv,
                                 const int eflag, const int vflag,
                                 const int inum, const int nbor_pitch,
                                 const __global numtyp *restrict 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, ii, offset;
  atom_info(t_per_atom,ii,tid,offset);

  __local numtyp2 ljd[MAX_BIO_SHARED_TYPES];
  __local numtyp sp_lj[8];
  if (tid<8)
    sp_lj[tid]=sp_lj_in[tid];
  if (tid<MAX_BIO_SHARED_TYPES)
    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) {
    int nbor, nbor_end;
    int i, numj;
    __local int n_stride;
    nbor_info(dev_nbor,dev_packed,nbor_pitch,t_per_atom,ii,offset,i,numj,
              n_stride,nbor_end,nbor);

    numtyp4 ix; fetch4(ix,i,pos_tex); //x_[i];
    numtyp qtmp; fetch(qtmp,i,q_tex);
    int itype=ix.w;

    for ( ; nbor<nbor_end; nbor+=n_stride) {
      int j=dev_packed[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; fetch4(jx,j,pos_tex); //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 = delx*delx+dely*dely+delz*delz;

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

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

          numtyp sig_r_6 = sig6*sig6*r2inv;
          sig_r_6 = sig_r_6*sig_r_6*sig_r_6;
          lj4 = (numtyp)4.0*eps*sig_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)12.0*rsq*switch1*(rsq-cut_lj_innersq)/
                             denom_lj;
            switch1 *= switch1;
            switch1 *= (cut_ljsq+(numtyp)2.0*rsq-(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 = ucl_rsqrt(r2inv);
          numtyp grij = g_ewald * r;
          numtyp expm2 = ucl_exp(-grij*grij);
          numtyp t = ucl_recip((numtyp)1.0 + EWALD_P*grij);
          _erfc = t * (A1+t*(A2+t*(A3+t*(A4+t*A5)))) * expm2;
          fetch(prefactor,j,q_tex);
          prefactor *= qqrd2e * qtmp/r;
          forcecoul = prefactor * (_erfc + EWALD_F*grij*expm2-factor_coul);
        } else
          forcecoul = (numtyp)0.0;

        force = (force_lj + forcecoul) * r2inv;

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

        if (eflag>0) {
          if (rsq < cut_coulsq)
            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] += delx*delx*force;
          virial[1] += dely*dely*force;
          virial[2] += delz*delz*force;
          virial[3] += delx*dely*force;
          virial[4] += delx*delz*force;
          virial[5] += dely*delz*force;
        }
      }

    } // for nbor
    store_answers_q(f,energy,e_coul,virial,ii,inum,tid,t_per_atom,offset,eflag,
                    vflag,ans,engv);
  } // if ii
}