improper_harmonic_kokkos.cpp
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Created: Fri, May 24, 20:06

improper_harmonic_kokkos.cpp
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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 author: Stan Moore (SNL)
	------------------------------------------------------------------------- */

	#include <mpi.h>
	#include <math.h>
	#include <stdlib.h>
	#include "improper_harmonic_kokkos.h"
	#include "atom_kokkos.h"
	#include "comm.h"
	#include "neighbor_kokkos.h"
	#include "domain.h"
	#include "force.h"
	#include "update.h"
	#include "math_const.h"
	#include "memory.h"
	#include "error.h"
	#include "atom_masks.h"

	using namespace LAMMPS_NS;
	using namespace MathConst;

	#define TOLERANCE 0.05
	#define SMALL 0.001

	/* ---------------------------------------------------------------------- */

	template<class DeviceType>
	ImproperHarmonicKokkos<DeviceType>::ImproperHarmonicKokkos(LAMMPS *lmp) : ImproperHarmonic(lmp)
	{
	atomKK = (AtomKokkos *) atom;
	neighborKK = (NeighborKokkos *) neighbor;
	execution_space = ExecutionSpaceFromDevice<DeviceType>::space;
	datamask_read = X_MASK \| F_MASK \| ENERGY_MASK \| VIRIAL_MASK;
	datamask_modify = F_MASK \| ENERGY_MASK \| VIRIAL_MASK;

	k_warning_flag = Kokkos::DualView<int,DeviceType>("Dihedral:warning_flag");
	d_warning_flag = k_warning_flag.template view<DeviceType>();
	h_warning_flag = k_warning_flag.h_view;
	}

	/* ---------------------------------------------------------------------- */

	template<class DeviceType>
	ImproperHarmonicKokkos<DeviceType>::~ImproperHarmonicKokkos()
	{
	if (!copymode) {
	memory->destroy_kokkos(k_eatom,eatom);
	memory->destroy_kokkos(k_vatom,vatom);
	}
	}

	/* ---------------------------------------------------------------------- */

	template<class DeviceType>
	void ImproperHarmonicKokkos<DeviceType>::compute(int eflag_in, int vflag_in)
	{
	eflag = eflag_in;
	vflag = vflag_in;

	if (eflag \|\| vflag) ev_setup(eflag,vflag,0);
	else evflag = 0;

	// reallocate per-atom arrays if necessary

	if (eflag_atom) {
	//if(k_eatom.dimension_0()<maxeatom) { // won't work without adding zero functor
	memory->destroy_kokkos(k_eatom,eatom);
	memory->create_kokkos(k_eatom,eatom,maxeatom,"improper:eatom");
	d_eatom = k_eatom.template view<DeviceType>();
	//}
	}
	if (vflag_atom) {
	//if(k_vatom.dimension_0()<maxvatom) { // won't work without adding zero functor
	memory->destroy_kokkos(k_vatom,vatom);
	memory->create_kokkos(k_vatom,vatom,maxvatom,6,"improper:vatom");
	d_vatom = k_vatom.template view<DeviceType>();
	//}
	}

	//atomKK->sync(execution_space,datamask_read);
	k_k.template sync<DeviceType>();
	k_chi.template sync<DeviceType>();
	if (eflag \|\| vflag) atomKK->modified(execution_space,datamask_modify);
	else atomKK->modified(execution_space,F_MASK);

	x = atomKK->k_x.view<DeviceType>();
	f = atomKK->k_f.view<DeviceType>();
	neighborKK->k_improperlist.template sync<DeviceType>();
	improperlist = neighborKK->k_improperlist.view<DeviceType>();
	int nimproperlist = neighborKK->nimproperlist;
	nlocal = atom->nlocal;
	newton_bond = force->newton_bond;

	h_warning_flag() = 0;
	k_warning_flag.template modify<LMPHostType>();
	k_warning_flag.template sync<DeviceType>();

	copymode = 1;

	// loop over neighbors of my atoms

	EV_FLOAT ev;

	if (evflag) {
	if (newton_bond) {
	Kokkos::parallel_reduce(Kokkos::RangePolicy<DeviceType, TagImproperHarmonicCompute<1,1> >(0,nimproperlist),*this,ev);
	} else {
	Kokkos::parallel_reduce(Kokkos::RangePolicy<DeviceType, TagImproperHarmonicCompute<0,1> >(0,nimproperlist),*this,ev);
	}
	} else {
	if (newton_bond) {
	Kokkos::parallel_for(Kokkos::RangePolicy<DeviceType, TagImproperHarmonicCompute<1,0> >(0,nimproperlist),*this);
	} else {
	Kokkos::parallel_for(Kokkos::RangePolicy<DeviceType, TagImproperHarmonicCompute<0,0> >(0,nimproperlist),*this);
	}
	}
	//DeviceType::fence();

	// error check

	k_warning_flag.template modify<DeviceType>();
	k_warning_flag.template sync<LMPHostType>();
	if (h_warning_flag())
	error->warning(FLERR,"Dihedral problem",0);

	if (eflag_global) energy += ev.evdwl;
	if (vflag_global) {
	virial[0] += ev.v[0];
	virial[1] += ev.v[1];
	virial[2] += ev.v[2];
	virial[3] += ev.v[3];
	virial[4] += ev.v[4];
	virial[5] += ev.v[5];
	}

	if (eflag_atom) {
	k_eatom.template modify<DeviceType>();
	k_eatom.template sync<LMPHostType>();
	}

	if (vflag_atom) {
	k_vatom.template modify<DeviceType>();
	k_vatom.template sync<LMPHostType>();
	}

	copymode = 0;
	}

	template<class DeviceType>
	template<int NEWTON_BOND, int EVFLAG>
	KOKKOS_INLINE_FUNCTION
	void ImproperHarmonicKokkos<DeviceType>::operator()(TagImproperHarmonicCompute<NEWTON_BOND,EVFLAG>, const int &n, EV_FLOAT& ev) const {

	const int i1 = improperlist(n,0);
	const int i2 = improperlist(n,1);
	const int i3 = improperlist(n,2);
	const int i4 = improperlist(n,3);
	const int type = improperlist(n,4);

	// geometry of 4-body

	const F_FLOAT vb1x = x(i1,0) - x(i2,0);
	const F_FLOAT vb1y = x(i1,1) - x(i2,1);
	const F_FLOAT vb1z = x(i1,2) - x(i2,2);

	const F_FLOAT vb2x = x(i3,0) - x(i2,0);
	const F_FLOAT vb2y = x(i3,1) - x(i2,1);
	const F_FLOAT vb2z = x(i3,2) - x(i2,2);

	const F_FLOAT vb3x = x(i4,0) - x(i3,0);
	const F_FLOAT vb3y = x(i4,1) - x(i3,1);
	const F_FLOAT vb3z = x(i4,2) - x(i3,2);

	const F_FLOAT ss1 = 1.0 / (vb1xvb1x + vb1yvb1y + vb1z*vb1z);
	const F_FLOAT ss2 = 1.0 / (vb2xvb2x + vb2yvb2y + vb2z*vb2z);
	const F_FLOAT ss3 = 1.0 / (vb3xvb3x + vb3yvb3y + vb3z*vb3z);

	const F_FLOAT r1 = sqrt(ss1);
	const F_FLOAT r2 = sqrt(ss2);
	const F_FLOAT r3 = sqrt(ss3);

	// sin and cos of improper

	const F_FLOAT c0 = (vb1x * vb3x + vb1y * vb3y + vb1z * vb3z) * r1 * r3;
	const F_FLOAT c1 = (vb1x * vb2x + vb1y * vb2y + vb1z * vb2z) * r1 * r2;
	const F_FLOAT c2 = -(vb3x * vb2x + vb3y * vb2y + vb3z * vb2z) * r3 * r2;

	F_FLOAT s1 = 1.0 - c1*c1;
	if (s1 < SMALL) s1 = SMALL;
	s1 = 1.0 / s1;

	F_FLOAT s2 = 1.0 - c2*c2;
	if (s2 < SMALL) s2 = SMALL;
	s2 = 1.0 / s2;

	F_FLOAT s12 = sqrt(s1*s2);
	F_FLOAT c = (c1c2 + c0) s12;

	// error check

	if ((c > 1.0 + TOLERANCE \|\| c < (-1.0 - TOLERANCE)) && !d_warning_flag())
	Kokkos::atomic_fetch_add(&d_warning_flag(),1);

	if (c > 1.0) c = 1.0;
	if (c < -1.0) c = -1.0;

	F_FLOAT s = sqrt(1.0 - c*c);
	if (s < SMALL) s = SMALL;

	// force & energy

	const F_FLOAT domega = acos(c) - d_chi[type];
	F_FLOAT a = d_k[type] * domega;

	F_FLOAT eimproper = 0.0;
	if (eflag) eimproper = a*domega;

	a = -a * 2.0/s;
	c = c * a;
	s12 = s12 * a;
	const F_FLOAT a11 = css1s1;
	const F_FLOAT a22 = -ss2 * (2.0c0s12 - c*(s1+s2));
	const F_FLOAT a33 = css3s2;
	const F_FLOAT a12 = -r1r2(c1cs1 + c2*s12);
	const F_FLOAT a13 = -r1r3s12;
	const F_FLOAT a23 = r2r3(c2cs2 + c1*s12);

	const F_FLOAT sx2 = a22vb2x + a23vb3x + a12*vb1x;
	const F_FLOAT sy2 = a22vb2y + a23vb3y + a12*vb1y;
	const F_FLOAT sz2 = a22vb2z + a23vb3z + a12*vb1z;

	F_FLOAT f1[3],f2[3],f3[3],f4[3];
	f1[0] = a12vb2x + a13vb3x + a11*vb1x;
	f1[1] = a12vb2y + a13vb3y + a11*vb1y;
	f1[2] = a12vb2z + a13vb3z + a11*vb1z;

	f2[0] = -sx2 - f1[0];
	f2[1] = -sy2 - f1[1];
	f2[2] = -sz2 - f1[2];

	f4[0] = a23vb2x + a33vb3x + a13*vb1x;
	f4[1] = a23vb2y + a33vb3y + a13*vb1y;
	f4[2] = a23vb2z + a33vb3z + a13*vb1z;

	f3[0] = sx2 - f4[0];
	f3[1] = sy2 - f4[1];
	f3[2] = sz2 - f4[2];

	// apply force to each of 4 atoms

	if (NEWTON_BOND \|\| i1 < nlocal) {
	f(i1,0) += f1[0];
	f(i1,1) += f1[1];
	f(i1,2) += f1[2];
	}

	if (NEWTON_BOND \|\| i2 < nlocal) {
	f(i2,0) += f2[0];
	f(i2,1) += f2[1];
	f(i2,2) += f2[2];
	}

	if (NEWTON_BOND \|\| i3 < nlocal) {
	f(i3,0) += f3[0];
	f(i3,1) += f3[1];
	f(i3,2) += f3[2];
	}

	if (NEWTON_BOND \|\| i4 < nlocal) {
	f(i4,0) += f4[0];
	f(i4,1) += f4[1];
	f(i4,2) += f4[2];
	}

	if (EVFLAG)
	ev_tally(ev,i1,i2,i3,i4,eimproper,f1,f3,f4,
	vb1x,vb1y,vb1z,vb2x,vb2y,vb2z,vb3x,vb3y,vb3z);
	}

	template<class DeviceType>
	template<int NEWTON_BOND, int EVFLAG>
	KOKKOS_INLINE_FUNCTION
	void ImproperHarmonicKokkos<DeviceType>::operator()(TagImproperHarmonicCompute<NEWTON_BOND,EVFLAG>, const int &n) const {
	EV_FLOAT ev;
	this->template operator()<NEWTON_BOND,EVFLAG>(TagImproperHarmonicCompute<NEWTON_BOND,EVFLAG>(), n, ev);
	}

	/* ---------------------------------------------------------------------- */

	template<class DeviceType>
	void ImproperHarmonicKokkos<DeviceType>::allocate()
	{
	ImproperHarmonic::allocate();

	int n = atom->nimpropertypes;
	k_k = Kokkos::DualView<F_FLOAT*,DeviceType>("ImproperHarmonic::k",n+1);
	k_chi = Kokkos::DualView<F_FLOAT*,DeviceType>("ImproperHarmonic::chi",n+1);

	d_k = k_k.d_view;
	d_chi = k_chi.d_view;
	}

	/* ----------------------------------------------------------------------
	set coeffs for one type
	------------------------------------------------------------------------- */

	template<class DeviceType>
	void ImproperHarmonicKokkos<DeviceType>::coeff(int narg, char **arg)
	{
	ImproperHarmonic::coeff(narg, arg);

	int n = atom->nimpropertypes;
	for (int i = 1; i <= n; i++) {
	k_k.h_view[i] = k[i];
	k_chi.h_view[i] = chi[i];
	}

	k_k.template modify<LMPHostType>();
	k_chi.template modify<LMPHostType>();
	}

	/* ----------------------------------------------------------------------
	tally energy and virial into global and per-atom accumulators
	virial = r1F1 + r2F2 + r3F3 + r4F4 = (r1-r2) F1 + (r3-r2) F3 + (r4-r2) F4
	= (r1-r2) F1 + (r3-r2) F3 + (r4-r3 + r3-r2) F4
	= vb1f1 + vb2f3 + (vb3+vb2)*f4
	------------------------------------------------------------------------- */

	template<class DeviceType>
	//template<int NEWTON_BOND>
	KOKKOS_INLINE_FUNCTION
	void ImproperHarmonicKokkos<DeviceType>::ev_tally(EV_FLOAT &ev, const int i1, const int i2, const int i3, const int i4,
	F_FLOAT &eimproper, F_FLOAT f1, F_FLOAT f3, F_FLOAT *f4,
	const F_FLOAT &vb1x, const F_FLOAT &vb1y, const F_FLOAT &vb1z,
	const F_FLOAT &vb2x, const F_FLOAT &vb2y, const F_FLOAT &vb2z,
	const F_FLOAT &vb3x, const F_FLOAT &vb3y, const F_FLOAT &vb3z) const
	{
	E_FLOAT eimproperquarter;
	F_FLOAT v[6];


	if (eflag_either) {
	if (eflag_global) {
	if (newton_bond) ev.evdwl += eimproper;
	else {
	eimproperquarter = 0.25*eimproper;
	if (i1 < nlocal) ev.evdwl += eimproperquarter;
	if (i2 < nlocal) ev.evdwl += eimproperquarter;
	if (i3 < nlocal) ev.evdwl += eimproperquarter;
	if (i4 < nlocal) ev.evdwl += eimproperquarter;
	}
	}
	if (eflag_atom) {
	eimproperquarter = 0.25*eimproper;
	if (newton_bond \|\| i1 < nlocal) d_eatom[i1] += eimproperquarter;
	if (newton_bond \|\| i2 < nlocal) d_eatom[i2] += eimproperquarter;
	if (newton_bond \|\| i3 < nlocal) d_eatom[i3] += eimproperquarter;
	if (newton_bond \|\| i4 < nlocal) d_eatom[i4] += eimproperquarter;
	}
	}

	if (vflag_either) {
	v[0] = vb1xf1[0] + vb2xf3[0] + (vb3x+vb2x)*f4[0];
	v[1] = vb1yf1[1] + vb2yf3[1] + (vb3y+vb2y)*f4[1];
	v[2] = vb1zf1[2] + vb2zf3[2] + (vb3z+vb2z)*f4[2];
	v[3] = vb1xf1[1] + vb2xf3[1] + (vb3x+vb2x)*f4[1];
	v[4] = vb1xf1[2] + vb2xf3[2] + (vb3x+vb2x)*f4[2];
	v[5] = vb1yf1[2] + vb2yf3[2] + (vb3y+vb2y)*f4[2];

	if (vflag_global) {
	if (newton_bond) {
	ev.v[0] += v[0];
	ev.v[1] += v[1];
	ev.v[2] += v[2];
	ev.v[3] += v[3];
	ev.v[4] += v[4];
	ev.v[5] += v[5];
	} else {
	if (i1 < nlocal) {
	ev.v[0] += 0.25*v[0];
	ev.v[1] += 0.25*v[1];
	ev.v[2] += 0.25*v[2];
	ev.v[3] += 0.25*v[3];
	ev.v[4] += 0.25*v[4];
	ev.v[5] += 0.25*v[5];
	}
	if (i2 < nlocal) {
	ev.v[0] += 0.25*v[0];
	ev.v[1] += 0.25*v[1];
	ev.v[2] += 0.25*v[2];
	ev.v[3] += 0.25*v[3];
	ev.v[4] += 0.25*v[4];
	ev.v[5] += 0.25*v[5];
	}
	if (i3 < nlocal) {
	ev.v[0] += 0.25*v[0];
	ev.v[1] += 0.25*v[1];
	ev.v[2] += 0.25*v[2];
	ev.v[3] += 0.25*v[3];
	ev.v[4] += 0.25*v[4];
	ev.v[5] += 0.25*v[5];
	}
	if (i4 < nlocal) {
	ev.v[0] += 0.25*v[0];
	ev.v[1] += 0.25*v[1];
	ev.v[2] += 0.25*v[2];
	ev.v[3] += 0.25*v[3];
	ev.v[4] += 0.25*v[4];
	ev.v[5] += 0.25*v[5];
	}
	}
	}

	if (vflag_atom) {
	if (newton_bond \|\| i1 < nlocal) {
	d_vatom(i1,0) += 0.25*v[0];
	d_vatom(i1,1) += 0.25*v[1];
	d_vatom(i1,2) += 0.25*v[2];
	d_vatom(i1,3) += 0.25*v[3];
	d_vatom(i1,4) += 0.25*v[4];
	d_vatom(i1,5) += 0.25*v[5];
	}
	if (newton_bond \|\| i2 < nlocal) {
	d_vatom(i2,0) += 0.25*v[0];
	d_vatom(i2,1) += 0.25*v[1];
	d_vatom(i2,2) += 0.25*v[2];
	d_vatom(i2,3) += 0.25*v[3];
	d_vatom(i2,4) += 0.25*v[4];
	d_vatom(i2,5) += 0.25*v[5];
	}
	if (newton_bond \|\| i3 < nlocal) {
	d_vatom(i3,0) += 0.25*v[0];
	d_vatom(i3,1) += 0.25*v[1];
	d_vatom(i3,2) += 0.25*v[2];
	d_vatom(i3,3) += 0.25*v[3];
	d_vatom(i3,4) += 0.25*v[4];
	d_vatom(i3,5) += 0.25*v[5];
	}
	if (newton_bond \|\| i4 < nlocal) {
	d_vatom(i4,0) += 0.25*v[0];
	d_vatom(i4,1) += 0.25*v[1];
	d_vatom(i4,2) += 0.25*v[2];
	d_vatom(i4,3) += 0.25*v[3];
	d_vatom(i4,4) += 0.25*v[4];
	d_vatom(i4,5) += 0.25*v[5];
	}
	}
	}
	}

	/* ---------------------------------------------------------------------- */

	namespace LAMMPS_NS {
	template class ImproperHarmonicKokkos<LMPDeviceType>;
	#ifdef KOKKOS_HAVE_CUDA
	template class ImproperHarmonicKokkos<LMPHostType>;
	#endif
	}

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