forked from lijiext/lammps
405 lines
12 KiB
C++
405 lines
12 KiB
C++
/***************************************************************************
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pppm.cpp
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-------------------
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W. Michael Brown (ORNL)
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Class for PPPM acceleration
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__________________________________________________________________________
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This file is part of the LAMMPS Accelerator Library (LAMMPS_AL)
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__________________________________________________________________________
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begin :
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email : brownw@ornl.gov
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***************************************************************************/
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#if defined(USE_OPENCL)
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#include "pppm_cl.h"
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#elif defined(USE_CUDART)
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const char *pppm_f=0;
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const char *pppm_d=0;
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#else
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#include "pppm_f_cubin.h"
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#include "pppm_d_cubin.h"
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#endif
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#include "lal_pppm.h"
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#include <cassert>
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using namespace LAMMPS_AL;
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#define PPPMT PPPM<numtyp, acctyp, grdtyp, grdtyp4>
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extern Device<PRECISION,ACC_PRECISION> global_device;
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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PPPMT::PPPM() : _allocated(false), _compiled(false),
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_max_bytes(0) {
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device=&global_device;
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ans=new Answer<numtyp,acctyp>();
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}
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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PPPMT::~PPPM() {
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clear(0.0);
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delete ans;
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}
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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int PPPMT::bytes_per_atom() const {
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return device->atom.bytes_per_atom()+ans->bytes_per_atom()+1;
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}
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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grdtyp * PPPMT::init(const int nlocal, const int nall, FILE *_screen,
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const int order, const int nxlo_out,
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const int nylo_out, const int nzlo_out,
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const int nxhi_out, const int nyhi_out,
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const int nzhi_out, grdtyp **rho_coeff,
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grdtyp **vd_brick_p, const double slab_volfactor,
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const int nx_pppm, const int ny_pppm,
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const int nz_pppm, const bool split, int &flag) {
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_max_bytes=10;
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screen=_screen;
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_kspace_split=split;
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bool success=true;
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flag=device->init(*ans,nlocal,nall);
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if (flag!=0)
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return 0;
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if (sizeof(grdtyp)==sizeof(double) && device->double_precision()==false) {
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flag=-5;
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return 0;
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}
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if (device->ptx_arch()>0.0 && device->ptx_arch()<1.1) {
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flag=-4;
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return 0;
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}
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ucl_device=device->gpu;
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atom=&device->atom;
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_block_size=device->pppm_block();
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_pencil_size=device->num_mem_threads();
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_block_pencils=_block_size/_pencil_size;
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compile_kernels(*ucl_device);
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// Initialize timers for the selected GPU
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time_in.init(*ucl_device);
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time_in.zero();
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time_out.init(*ucl_device);
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time_out.zero();
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time_map.init(*ucl_device);
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time_map.zero();
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time_rho.init(*ucl_device);
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time_rho.zero();
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time_interp.init(*ucl_device);
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time_interp.zero();
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pos_tex.bind_float(atom->x,4);
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q_tex.bind_float(atom->q,1);
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_allocated=true;
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_max_bytes=0;
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_max_an_bytes=ans->gpu_bytes();
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_order=order;
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_order_m_1=order-1;
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_order2=_order_m_1*_order;
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_nlower=-(_order-1)/2;
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_nupper=order/2;
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_nxlo_out=nxlo_out;
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_nylo_out=nylo_out;
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_nzlo_out=nzlo_out;
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_nxhi_out=nxhi_out;
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_nyhi_out=nyhi_out;
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_nzhi_out=nzhi_out;
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_slab_volfactor=slab_volfactor;
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_nx_pppm=nx_pppm;
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_ny_pppm=ny_pppm;
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_nz_pppm=nz_pppm;
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_max_brick_atoms=10;
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// Get rho_coeff on device
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int n2lo=(1-order)/2;
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int numel=order*( order/2 - n2lo + 1 );
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success=success && (d_rho_coeff.alloc(numel,*ucl_device,UCL_READ_ONLY)==
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UCL_SUCCESS);
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UCL_H_Vec<grdtyp> view;
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view.view(rho_coeff[0]+n2lo,numel,*ucl_device);
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ucl_copy(d_rho_coeff,view,true);
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_max_bytes+=d_rho_coeff.row_bytes();
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// Allocate storage for grid
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_npts_x=nxhi_out-nxlo_out+1;
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_npts_y=nyhi_out-nylo_out+1;
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_npts_z=nzhi_out-nzlo_out+1;
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_npts_yx=_npts_x*_npts_y;
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success=success && (brick.alloc(_npts_x*_npts_y*_npts_z,*ucl_device,
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UCL_READ_ONLY,UCL_WRITE_ONLY)==UCL_SUCCESS);
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success=success && (vd_brick.alloc(_npts_x*_npts_y*_npts_z*4,*ucl_device,
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UCL_READ_WRITE,UCL_READ_ONLY)==UCL_SUCCESS);
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*vd_brick_p=vd_brick.host.begin();
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_max_bytes+=brick.device.row_bytes()+vd_brick.device.row_bytes();
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// Allocate vector with count of atoms assigned to each grid point
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_nlocal_x=_npts_x+_nlower-_nupper;
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_nlocal_y=_npts_y+_nlower-_nupper;
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_nlocal_z=_npts_z+_nlower-_nupper;
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_nlocal_yx=_nlocal_x*_nlocal_y;
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_atom_stride=_nlocal_x*_nlocal_y*_nlocal_z;
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success=success && (d_brick_counts.alloc(_atom_stride,*ucl_device)==
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UCL_SUCCESS);
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_max_bytes+=d_brick_counts.row_bytes();
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// Allocate storage for atoms assigned to each grid point
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success=success && (d_brick_atoms.alloc(_atom_stride*_max_brick_atoms,
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*ucl_device)==UCL_SUCCESS);
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_max_bytes+=d_brick_atoms.row_bytes();
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// Allocate error flags for checking out of bounds atoms
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success=success && (error_flag.alloc(1,*ucl_device,UCL_READ_ONLY,
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UCL_WRITE_ONLY)==UCL_SUCCESS);
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if (!success) {
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flag=-3;
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return 0;
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}
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error_flag.device.zero();
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_max_bytes+=1;
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_cpu_idle_time=0.0;
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return brick.host.begin();
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}
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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void PPPMT::clear(const double cpu_time) {
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if (!_allocated)
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return;
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_allocated=false;
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_precompute_done=false;
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brick.clear();
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vd_brick.clear();
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d_brick_counts.clear();
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error_flag.clear();
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d_brick_atoms.clear();
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acc_timers();
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device->output_kspace_times(time_in,time_out,time_map,time_rho,time_interp,
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*ans,_max_bytes+_max_an_bytes,cpu_time,
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_cpu_idle_time,screen);
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if (_compiled) {
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k_particle_map.clear();
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k_make_rho.clear();
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k_interp.clear();
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delete pppm_program;
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_compiled=false;
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}
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time_in.clear();
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time_out.clear();
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time_map.clear();
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time_rho.clear();
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time_interp.clear();
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ans->clear();
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device->clear();
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}
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// ---------------------------------------------------------------------------
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// Charge assignment that can be performed asynchronously
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// ---------------------------------------------------------------------------
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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void PPPMT::_precompute(const int ago, const int nlocal, const int nall,
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double **host_x, int *host_type, bool &success,
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double *host_q, double *boxlo,
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const double delxinv, const double delyinv,
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const double delzinv) {
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acc_timers();
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if (nlocal==0) {
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zero_timers();
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return;
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}
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ans->inum(nlocal);
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if (ago==0) {
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resize_atom(nlocal,nall,success);
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resize_local(nlocal,success);
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if (!success)
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return;
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double bytes=ans->gpu_bytes();
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if (bytes>_max_an_bytes)
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_max_an_bytes=bytes;
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}
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atom->cast_x_data(host_x,host_type);
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atom->cast_q_data(host_q);
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atom->add_x_data(host_x,host_type);
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atom->add_q_data();
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time_map.start();
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// Compute the block size and grid size to keep all cores busy
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int BX=this->block_size();
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int GX=static_cast<int>(ceil(static_cast<double>(this->ans->inum())/BX));
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int ainum=this->ans->inum();
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// Boxlo adjusted to be upper left brick and shift for even spline order
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double shift=0.0;
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if (_order % 2)
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shift=0.5;
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_brick_x=boxlo[0]+(_nxlo_out-_nlower-shift)/delxinv;
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_brick_y=boxlo[1]+(_nylo_out-_nlower-shift)/delyinv;
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_brick_z=boxlo[2]+(_nzlo_out-_nlower-shift)/delzinv;
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_delxinv=delxinv;
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_delyinv=delyinv;
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_delzinv=delzinv;
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double delvolinv = delxinv*delyinv*delzinv;
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grdtyp f_delvolinv = delvolinv;
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device->zero(d_brick_counts,d_brick_counts.numel());
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k_particle_map.set_size(GX,BX);
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k_particle_map.run(&atom->x, &atom->q, &f_delvolinv, &ainum,
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&d_brick_counts, &d_brick_atoms, &_brick_x, &_brick_y,
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&_brick_z, &_delxinv, &_delyinv, &_delzinv, &_nlocal_x,
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&_nlocal_y, &_nlocal_z, &_atom_stride, &_max_brick_atoms,
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&error_flag);
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time_map.stop();
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time_rho.start();
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BX=block_size();
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GX=static_cast<int>(ceil(static_cast<double>(_npts_y*_npts_z)/
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_block_pencils));
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k_make_rho.set_size(GX,BX);
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k_make_rho.run(&d_brick_counts, &d_brick_atoms, &brick, &d_rho_coeff,
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&_atom_stride, &_npts_x, &_npts_y, &_npts_z, &_nlocal_x,
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&_nlocal_y, &_nlocal_z, &_order_m_1, &_order, &_order2);
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time_rho.stop();
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time_out.start();
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brick.update_host(_npts_yx*_npts_z,true);
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error_flag.update_host(true);
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time_out.stop();
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_precompute_done=true;
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}
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// ---------------------------------------------------------------------------
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// Charge spreading stuff
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// ---------------------------------------------------------------------------
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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int PPPMT::spread(const int ago, const int nlocal, const int nall,
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double **host_x, int *host_type, bool &success,
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double *host_q, double *boxlo,
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const double delxinv, const double delyinv,
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const double delzinv) {
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if (_precompute_done==false) {
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atom->acc_timers();
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_precompute(ago,nlocal,nall,host_x,host_type,success,host_q,boxlo,delxinv,
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delyinv,delzinv);
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}
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device->stop_host_timer();
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if (!success || nlocal==0)
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return 0;
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double t=MPI_Wtime();
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time_out.sync_stop();
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_cpu_idle_time+=MPI_Wtime()-t;
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_precompute_done=false;
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if (error_flag[0]==2) {
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// Not enough storage for atoms on the brick
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_max_brick_atoms*=2;
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error_flag.device.zero();
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d_brick_atoms.resize(_atom_stride*_max_brick_atoms);
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_max_bytes+=d_brick_atoms.row_bytes();
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return spread(ago,nlocal,nall,host_x,host_type,success,host_q,boxlo,
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delxinv,delyinv,delzinv);
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}
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return error_flag[0];
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}
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// ---------------------------------------------------------------------------
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// Charge spreading stuff
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// ---------------------------------------------------------------------------
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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void PPPMT::interp(const grdtyp qqrd2e_scale) {
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time_in.start();
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vd_brick.update_device(true);
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time_in.stop();
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time_interp.start();
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// Compute the block size and grid size to keep all cores busy
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int BX=this->block_size();
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int GX=static_cast<int>(ceil(static_cast<double>(this->ans->inum())/BX));
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int ainum=this->ans->inum();
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k_interp.set_size(GX,BX);
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k_interp.run(&atom->x, &atom->q, &ainum, &vd_brick, &d_rho_coeff,
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&_npts_x, &_npts_yx, &_brick_x, &_brick_y, &_brick_z, &_delxinv,
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&_delyinv, &_delzinv, &_order, &_order2, &qqrd2e_scale,
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&ans->force);
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time_interp.stop();
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ans->copy_answers(false,false,false,false);
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if (_kspace_split==false)
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device->add_ans_object(ans);
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}
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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double PPPMT::host_memory_usage() const {
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return device->atom.host_memory_usage()+
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sizeof(PPPM<numtyp,acctyp,grdtyp,grdtyp4>);
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}
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template <class numtyp, class acctyp, class grdtyp, class grdtyp4>
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void PPPMT::compile_kernels(UCL_Device &dev) {
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if (_compiled)
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return;
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if (sizeof(grdtyp)==sizeof(double) && ucl_device->double_precision()==false)
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return;
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std::string flags=device->compile_string();
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#ifdef USE_OPENCL
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flags+=std::string(" -Dgrdtyp=")+ucl_template_name<grdtyp>()+" -Dgrdtyp4="+
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ucl_template_name<grdtyp>()+"4";
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#endif
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pppm_program=new UCL_Program(dev);
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#ifdef USE_OPENCL
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pppm_program->load_string(pppm,flags.c_str());
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#else
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if (sizeof(grdtyp)==sizeof(float))
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pppm_program->load_string(pppm_f,flags.c_str());
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else
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pppm_program->load_string(pppm_d,flags.c_str());
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#endif
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k_particle_map.set_function(*pppm_program,"particle_map");
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k_make_rho.set_function(*pppm_program,"make_rho");
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k_interp.set_function(*pppm_program,"interp");
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pos_tex.get_texture(*pppm_program,"pos_tex");
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q_tex.get_texture(*pppm_program,"q_tex");
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_compiled=true;
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}
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template class PPPM<PRECISION,ACC_PRECISION,float,_lgpu_float4>;
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template class PPPM<PRECISION,ACC_PRECISION,double,_lgpu_double4>;
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