MD-Bench/src/neighbor.c

/*
 * =======================================================================================
 *
 *   Author:   Jan Eitzinger (je), jan.eitzinger@fau.de
 *   Copyright (c) 2021 RRZE, University Erlangen-Nuremberg
 *
 *   This file is part of MD-Bench.
 *
 *   MD-Bench is free software: you can redistribute it and/or modify it
 *   under the terms of the GNU Lesser General Public License as published
 *   by the Free Software Foundation, either version 3 of the License, or
 *   (at your option) any later version.
 *
 *   MD-Bench is distributed in the hope that it will be useful, but WITHOUT ANY
 *   WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A
 *   PARTICULAR PURPOSE.  See the GNU Lesser General Public License for more
 *   details.
 *
 *   You should have received a copy of the GNU Lesser General Public License along
 *   with MD-Bench.  If not, see <https://www.gnu.org/licenses/>.
 * =======================================================================================
 */
#include <stdlib.h>
#include <stdio.h>
#include <math.h>

#include <neighbor.h>
#include <parameter.h>
#include <atom.h>

#define SMALL 1.0e-6
#define FACTOR 0.999

static MD_FLOAT xprd, yprd, zprd;
static MD_FLOAT bininvx, bininvy, bininvz;
static int mbinxlo, mbinylo, mbinzlo;
static int nbinx, nbiny, nbinz;
static int mbinx, mbiny, mbinz; // n bins in x, y, z
static int *bincount;
static int *bins;
static int mbins; //total number of bins
static int atoms_per_bin;  // max atoms per bin
static MD_FLOAT cutneigh;
static MD_FLOAT cutneighsq;  // neighbor cutoff squared
static int nmax;
static int nstencil;      // # of bins in stencil
static int* stencil;      // stencil list of bin offsets
static MD_FLOAT binsizex, binsizey, binsizez;

static int coord2bin(MD_FLOAT, MD_FLOAT , MD_FLOAT);
static MD_FLOAT bindist(int, int, int);

/* exported subroutines */
void initNeighbor(Neighbor *neighbor, Parameter *param)
{
    MD_FLOAT neighscale = 5.0 / 6.0;
    xprd = param->nx * param->lattice;
    yprd = param->ny * param->lattice;
    zprd = param->nz * param->lattice;
    cutneigh = param->cutneigh;
    nbinx = neighscale * param->nx;
    nbiny = neighscale * param->ny;
    nbinz = neighscale * param->nz;
    nmax = 0;
    atoms_per_bin = 8;
    stencil = NULL;
    bins = NULL;
    bincount = NULL;
    neighbor->maxneighs = 100;
    neighbor->numneigh = NULL;
    neighbor->neighbors = NULL;
}

void setupNeighbor()
{
    MD_FLOAT coord;
    int mbinxhi, mbinyhi, mbinzhi;
    int nextx, nexty, nextz;
    MD_FLOAT xlo = 0.0; MD_FLOAT xhi = xprd;
    MD_FLOAT ylo = 0.0; MD_FLOAT yhi = yprd;
    MD_FLOAT zlo = 0.0; MD_FLOAT zhi = zprd;

    cutneighsq = cutneigh * cutneigh;
    binsizex = xprd / nbinx;
    binsizey = yprd / nbiny;
    binsizez = zprd / nbinz;
    bininvx = 1.0 / binsizex;
    bininvy = 1.0 / binsizey;
    bininvz = 1.0 / binsizez;

    coord = xlo - cutneigh - SMALL * xprd;
    mbinxlo = (int) (coord * bininvx);
    if (coord < 0.0) {
        mbinxlo = mbinxlo - 1;
    }
    coord = xhi + cutneigh + SMALL * xprd;
    mbinxhi = (int) (coord * bininvx);

    coord = ylo - cutneigh - SMALL * yprd;
    mbinylo = (int) (coord * bininvy);
    if (coord < 0.0) {
        mbinylo = mbinylo - 1;
    }
    coord = yhi + cutneigh + SMALL * yprd;
    mbinyhi = (int) (coord * bininvy);

    coord = zlo - cutneigh - SMALL * zprd;
    mbinzlo = (int) (coord * bininvz);
    if (coord < 0.0) {
        mbinzlo = mbinzlo - 1;
    }
    coord = zhi + cutneigh + SMALL * zprd;
    mbinzhi = (int) (coord * bininvz);

    mbinxlo = mbinxlo - 1;
    mbinxhi = mbinxhi + 1;
    mbinx = mbinxhi - mbinxlo + 1;

    mbinylo = mbinylo - 1;
    mbinyhi = mbinyhi + 1;
    mbiny = mbinyhi - mbinylo + 1;

    mbinzlo = mbinzlo - 1;
    mbinzhi = mbinzhi + 1;
    mbinz = mbinzhi - mbinzlo + 1;

    nextx = (int) (cutneigh * bininvx);
    if(nextx * binsizex < FACTOR * cutneigh) nextx++;

    nexty = (int) (cutneigh * bininvy);
    if(nexty * binsizey < FACTOR * cutneigh) nexty++;

    nextz = (int) (cutneigh * bininvz);
    if(nextz * binsizez < FACTOR * cutneigh) nextz++;

    if (stencil) {
        free(stencil);
    }

    stencil = (int*) malloc(
            (2 * nextz + 1) * (2 * nexty + 1) * (2 * nextx + 1) * sizeof(int));

    nstencil = 0;
    int kstart = -nextz;

    for(int k = kstart; k <= nextz; k++) {
        for(int j = -nexty; j <= nexty; j++) {
            for(int i = -nextx; i <= nextx; i++) {
                if(bindist(i, j, k) < cutneighsq) {
                    stencil[nstencil++] =
                        k * mbiny * mbinx + j * mbinx + i;
                }
            }
        }
    }

    mbins = mbinx * mbiny * mbinz;

    if (bincount) {
        free(bincount);
    }
    bincount = (int*) malloc(mbins * sizeof(int));

    if (bins) {
        free(bins);
    }
    bins = (int*) malloc(mbins * atoms_per_bin * sizeof(int));
}

void buildNeighbor(Atom *atom, Neighbor *neighbor)
{
    int nall = atom->Nlocal + atom->Nghost;

    /* extend atom arrays if necessary */
    if(nall > nmax) {
        nmax = nall;
        if(neighbor->numneigh) free(neighbor->numneigh);
        if(neighbor->neighbors) free(neighbor->neighbors);
        neighbor->numneigh = (int*) malloc(nmax * sizeof(int));
        neighbor->neighbors = (int*) malloc(nmax * neighbor->maxneighs * sizeof(int*));
    }

    /* bin local & ghost atoms */
    binatoms(atom);
    int resize = 1;

    /* loop over each atom, storing neighbors */
    while(resize) {
        int new_maxneighs = neighbor->maxneighs;
        resize = 0;

        for(int i = 0; i < atom->Nlocal; i++) {
            int* neighptr = &(neighbor->neighbors[i * neighbor->maxneighs]);
            int n = 0;
            MD_FLOAT xtmp = atom_x(i);
            MD_FLOAT ytmp = atom_y(i);
            MD_FLOAT ztmp = atom_z(i);
            int ibin = coord2bin(xtmp, ytmp, ztmp);

            for(int k = 0; k < nstencil; k++) {
                int jbin = ibin + stencil[k];
                int* loc_bin = &bins[jbin * atoms_per_bin];

                for(int m = 0; m < bincount[jbin]; m++) {
                    int j = loc_bin[m];

                    if ( j == i ){
                        continue;
                    }

                    MD_FLOAT delx = xtmp - atom_x(j);
                    MD_FLOAT dely = ytmp - atom_y(j);
                    MD_FLOAT delz = ztmp - atom_z(j);
                    MD_FLOAT rsq = delx * delx + dely * dely + delz * delz;

                    if( rsq <= cutneighsq ) {
                        neighptr[n++] = j;
                    }
                }
            }

            neighbor->numneigh[i] = n;

            if(n >= neighbor->maxneighs) {
                resize = 1;

                if(n >= new_maxneighs) {
                    new_maxneighs = n;
                }
            }
        }

        if(resize) {
            printf("RESIZE %d\n", neighbor->maxneighs);
            neighbor->maxneighs = new_maxneighs * 1.2;
            free(neighbor->neighbors);
            neighbor->neighbors = (int*) malloc(atom->Nmax * neighbor->maxneighs * sizeof(int));
        }
    }
}

/* internal subroutines */
MD_FLOAT bindist(int i, int j, int k)
{
    MD_FLOAT delx, dely, delz;

    if(i > 0) {
        delx = (i - 1) * binsizex;
    } else if(i == 0) {
        delx = 0.0;
    } else {
        delx = (i + 1) * binsizex;
    }

    if(j > 0) {
        dely = (j - 1) * binsizey;
    } else if(j == 0) {
        dely = 0.0;
    } else {
        dely = (j + 1) * binsizey;
    }

    if(k > 0) {
        delz = (k - 1) * binsizez;
    } else if(k == 0) {
        delz = 0.0;
    } else {
        delz = (k + 1) * binsizez;
    }

    return (delx * delx + dely * dely + delz * delz);
}

int coord2bin(MD_FLOAT xin, MD_FLOAT yin, MD_FLOAT zin)
{
    int ix, iy, iz;

    if(xin >= xprd) {
        ix = (int)((xin - xprd) * bininvx) + nbinx - mbinxlo;
    } else if(xin >= 0.0) {
        ix = (int)(xin * bininvx) - mbinxlo;
    } else {
        ix = (int)(xin * bininvx) - mbinxlo - 1;
    }

    if(yin >= yprd) {
        iy = (int)((yin - yprd) * bininvy) + nbiny - mbinylo;
    } else if(yin >= 0.0) {
        iy = (int)(yin * bininvy) - mbinylo;
    } else {
        iy = (int)(yin * bininvy) - mbinylo - 1;
    }

    if(zin >= zprd) {
        iz = (int)((zin - zprd) * bininvz) + nbinz - mbinzlo;
    } else if(zin >= 0.0) {
        iz = (int)(zin * bininvz) - mbinzlo;
    } else {
        iz = (int)(zin * bininvz) - mbinzlo - 1;
    }

    return (iz * mbiny * mbinx + iy * mbinx + ix + 1);
}

void binatoms(Atom *atom)
{
    int nall = atom->Nlocal + atom->Nghost;
    int resize = 1;

    while(resize > 0) {
        resize = 0;

        for(int i = 0; i < mbins; i++) {
            bincount[i] = 0;
        }

        for(int i = 0; i < nall; i++) {
            int ibin = coord2bin(atom_x(i), atom_y(i), atom_z(i));

            if(bincount[ibin] < atoms_per_bin) {
                int ac = bincount[ibin]++;
                bins[ibin * atoms_per_bin + ac] = i;
            } else {
                resize = 1;
            }
        }

        if(resize) {
            free(bins);
            atoms_per_bin *= 2;
            bins = (int*) malloc(mbins * atoms_per_bin * sizeof(int));
        }
    }
}
Introduce modular version. 2020-08-18 14:27:28 +02:00			`/*`
			`* =======================================================================================`
			`*`
Switch License to LGPL3 2020-08-19 10:47:40 +02:00			`* Author: Jan Eitzinger (je), jan.eitzinger@fau.de`
Simplify macros for data structure access. Still segvaults for AoS. 2021-03-23 09:26:41 +01:00			`* Copyright (c) 2021 RRZE, University Erlangen-Nuremberg`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`*`
Switch License to LGPL3 2020-08-19 10:47:40 +02:00			`* This file is part of MD-Bench.`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`*`
Switch License to LGPL3 2020-08-19 10:47:40 +02:00			`* MD-Bench is free software: you can redistribute it and/or modify it`
			`* under the terms of the GNU Lesser General Public License as published`
			`* by the Free Software Foundation, either version 3 of the License, or`
			`* (at your option) any later version.`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`*`
Switch License to LGPL3 2020-08-19 10:47:40 +02:00			`* MD-Bench is distributed in the hope that it will be useful, but WITHOUT ANY`
			`* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A`
			`* PARTICULAR PURPOSE. See the GNU Lesser General Public License for more`
			`* details.`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`*`
Switch License to LGPL3 2020-08-19 10:47:40 +02:00			`* You should have received a copy of the GNU Lesser General Public License along`
			`* with MD-Bench. If not, see <https://www.gnu.org/licenses/>.`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`* =======================================================================================`
			`*/`
			`#include <stdlib.h>`
			`#include <stdio.h>`
			`#include <math.h>`

			`#include <neighbor.h>`
			`#include <parameter.h>`
			`#include <atom.h>`

			`#define SMALL 1.0e-6`
			`#define FACTOR 0.999`

Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`static MD_FLOAT xprd, yprd, zprd;`
			`static MD_FLOAT bininvx, bininvy, bininvz;`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`static int mbinxlo, mbinylo, mbinzlo;`
			`static int nbinx, nbiny, nbinz;`
			`static int mbinx, mbiny, mbinz; // n bins in x, y, z`
			`static int *bincount;`
			`static int *bins;`
			`static int mbins; //total number of bins`
			`static int atoms_per_bin; // max atoms per bin`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`static MD_FLOAT cutneigh;`
			`static MD_FLOAT cutneighsq; // neighbor cutoff squared`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`static int nmax;`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`static int nstencil; // # of bins in stencil`
			`static int* stencil; // stencil list of bin offsets`
			`static MD_FLOAT binsizex, binsizey, binsizez;`
Introduce modular version. 2020-08-18 14:27:28 +02:00
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`static int coord2bin(MD_FLOAT, MD_FLOAT , MD_FLOAT);`
			`static MD_FLOAT bindist(int, int, int);`
Introduce modular version. 2020-08-18 14:27:28 +02:00
			`/* exported subroutines */`
			`void initNeighbor(Neighbor neighbor, Parameter param)`
			`{`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`MD_FLOAT neighscale = 5.0 / 6.0;`
Add version with stubbed force calculation Signed-off-by: Rafael Ravedutti <rafaelravedutti@gmail.com> 2021-03-30 01:54:56 +02:00			`xprd = param->nx * param->lattice;`
			`yprd = param->ny * param->lattice;`
			`zprd = param->nz * param->lattice;`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`cutneigh = param->cutneigh;`
			`nbinx = neighscale * param->nx;`
			`nbiny = neighscale * param->ny;`
			`nbinz = neighscale * param->nz;`
			`nmax = 0;`
			`atoms_per_bin = 8;`
			`stencil = NULL;`
			`bins = NULL;`
			`bincount = NULL;`
			`neighbor->maxneighs = 100;`
			`neighbor->numneigh = NULL;`
			`neighbor->neighbors = NULL;`
			`}`

Refactor. Fix bug in atom initialization. 2020-08-19 09:00:35 +02:00			`void setupNeighbor()`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`{`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`MD_FLOAT coord;`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`int mbinxhi, mbinyhi, mbinzhi;`
			`int nextx, nexty, nextz;`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`MD_FLOAT xlo = 0.0; MD_FLOAT xhi = xprd;`
			`MD_FLOAT ylo = 0.0; MD_FLOAT yhi = yprd;`
			`MD_FLOAT zlo = 0.0; MD_FLOAT zhi = zprd;`
Introduce modular version. 2020-08-18 14:27:28 +02:00
			`cutneighsq = cutneigh * cutneigh;`
			`binsizex = xprd / nbinx;`
			`binsizey = yprd / nbiny;`
			`binsizez = zprd / nbinz;`
			`bininvx = 1.0 / binsizex;`
			`bininvy = 1.0 / binsizey;`
			`bininvz = 1.0 / binsizez;`

			`coord = xlo - cutneigh - SMALL * xprd;`
			`mbinxlo = (int) (coord * bininvx);`
			`if (coord < 0.0) {`
			`mbinxlo = mbinxlo - 1;`
			`}`
			`coord = xhi + cutneigh + SMALL * xprd;`
			`mbinxhi = (int) (coord * bininvx);`

			`coord = ylo - cutneigh - SMALL * yprd;`
			`mbinylo = (int) (coord * bininvy);`
			`if (coord < 0.0) {`
			`mbinylo = mbinylo - 1;`
			`}`
			`coord = yhi + cutneigh + SMALL * yprd;`
			`mbinyhi = (int) (coord * bininvy);`

			`coord = zlo - cutneigh - SMALL * zprd;`
			`mbinzlo = (int) (coord * bininvz);`
			`if (coord < 0.0) {`
			`mbinzlo = mbinzlo - 1;`
			`}`
			`coord = zhi + cutneigh + SMALL * zprd;`
			`mbinzhi = (int) (coord * bininvz);`

			`mbinxlo = mbinxlo - 1;`
			`mbinxhi = mbinxhi + 1;`
			`mbinx = mbinxhi - mbinxlo + 1;`

			`mbinylo = mbinylo - 1;`
			`mbinyhi = mbinyhi + 1;`
			`mbiny = mbinyhi - mbinylo + 1;`

			`mbinzlo = mbinzlo - 1;`
			`mbinzhi = mbinzhi + 1;`
			`mbinz = mbinzhi - mbinzlo + 1;`

			`nextx = (int) (cutneigh * bininvx);`
			`if(nextx * binsizex < FACTOR * cutneigh) nextx++;`

			`nexty = (int) (cutneigh * bininvy);`
			`if(nexty * binsizey < FACTOR * cutneigh) nexty++;`

			`nextz = (int) (cutneigh * bininvz);`
			`if(nextz * binsizez < FACTOR * cutneigh) nextz++;`

			`if (stencil) {`
			`free(stencil);`
			`}`

			`stencil = (int*) malloc(`
			`(2 * nextz + 1) * (2 * nexty + 1) * (2 * nextx + 1) * sizeof(int));`

			`nstencil = 0;`
			`int kstart = -nextz;`

			`for(int k = kstart; k <= nextz; k++) {`
			`for(int j = -nexty; j <= nexty; j++) {`
			`for(int i = -nextx; i <= nextx; i++) {`
			`if(bindist(i, j, k) < cutneighsq) {`
			`stencil[nstencil++] =`
			`k * mbiny * mbinx + j * mbinx + i;`
			`}`
			`}`
			`}`
			`}`

			`mbins = mbinx * mbiny * mbinz;`

			`if (bincount) {`
			`free(bincount);`
			`}`
			`bincount = (int) malloc(mbins sizeof(int));`

			`if (bins) {`
			`free(bins);`
			`}`
			`bins = (int) malloc(mbins atoms_per_bin * sizeof(int));`
			`}`

			`void buildNeighbor(Atom atom, Neighbor neighbor)`
			`{`
			`int nall = atom->Nlocal + atom->Nghost;`

			`/* extend atom arrays if necessary */`
			`if(nall > nmax) {`
			`nmax = nall;`
			`if(neighbor->numneigh) free(neighbor->numneigh);`
			`if(neighbor->neighbors) free(neighbor->neighbors);`
			`neighbor->numneigh = (int) malloc(nmax sizeof(int));`
			`neighbor->neighbors = (int) malloc(nmax neighbor->maxneighs * sizeof(int*));`
			`}`

			`/* bin local & ghost atoms */`
			`binatoms(atom);`
			`int resize = 1;`

			`/* loop over each atom, storing neighbors */`
			`while(resize) {`
			`int new_maxneighs = neighbor->maxneighs;`
			`resize = 0;`

			`for(int i = 0; i < atom->Nlocal; i++) {`
			`int* neighptr = &(neighbor->neighbors[i * neighbor->maxneighs]);`
			`int n = 0;`
Simplify macros for data structure access. Still segvaults for AoS. 2021-03-23 09:26:41 +01:00			`MD_FLOAT xtmp = atom_x(i);`
			`MD_FLOAT ytmp = atom_y(i);`
			`MD_FLOAT ztmp = atom_z(i);`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`int ibin = coord2bin(xtmp, ytmp, ztmp);`

			`for(int k = 0; k < nstencil; k++) {`
			`int jbin = ibin + stencil[k];`
			`int* loc_bin = &bins[jbin * atoms_per_bin];`

			`for(int m = 0; m < bincount[jbin]; m++) {`
			`int j = loc_bin[m];`

			`if ( j == i ){`
			`continue;`
			`}`

Simplify macros for data structure access. Still segvaults for AoS. 2021-03-23 09:26:41 +01:00			`MD_FLOAT delx = xtmp - atom_x(j);`
			`MD_FLOAT dely = ytmp - atom_y(j);`
			`MD_FLOAT delz = ztmp - atom_z(j);`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`MD_FLOAT rsq = delx * delx + dely * dely + delz * delz;`
Introduce modular version. 2020-08-18 14:27:28 +02:00
			`if( rsq <= cutneighsq ) {`
			`neighptr[n++] = j;`
			`}`
			`}`
			`}`

			`neighbor->numneigh[i] = n;`

			`if(n >= neighbor->maxneighs) {`
			`resize = 1;`

			`if(n >= new_maxneighs) {`
			`new_maxneighs = n;`
			`}`
			`}`
			`}`

			`if(resize) {`
			`printf("RESIZE %d\n", neighbor->maxneighs);`
			`neighbor->maxneighs = new_maxneighs * 1.2;`
			`free(neighbor->neighbors);`
			`neighbor->neighbors = (int) malloc(atom->Nmax neighbor->maxneighs * sizeof(int));`
			`}`
			`}`
			`}`

			`/* internal subroutines */`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`MD_FLOAT bindist(int i, int j, int k)`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`{`
Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`MD_FLOAT delx, dely, delz;`
Introduce modular version. 2020-08-18 14:27:28 +02:00
			`if(i > 0) {`
			`delx = (i - 1) * binsizex;`
			`} else if(i == 0) {`
			`delx = 0.0;`
			`} else {`
			`delx = (i + 1) * binsizex;`
			`}`

			`if(j > 0) {`
			`dely = (j - 1) * binsizey;`
			`} else if(j == 0) {`
			`dely = 0.0;`
			`} else {`
			`dely = (j + 1) * binsizey;`
			`}`

			`if(k > 0) {`
			`delz = (k - 1) * binsizez;`
			`} else if(k == 0) {`
			`delz = 0.0;`
			`} else {`
			`delz = (k + 1) * binsizez;`
			`}`

			`return (delx * delx + dely * dely + delz * delz);`
			`}`

Include Likwid Markers. Allow to switch between SP and DP floats. 2020-11-05 12:41:44 +01:00			`int coord2bin(MD_FLOAT xin, MD_FLOAT yin, MD_FLOAT zin)`
Introduce modular version. 2020-08-18 14:27:28 +02:00			`{`
			`int ix, iy, iz;`

			`if(xin >= xprd) {`
			`ix = (int)((xin - xprd) * bininvx) + nbinx - mbinxlo;`
			`} else if(xin >= 0.0) {`
			`ix = (int)(xin * bininvx) - mbinxlo;`
			`} else {`
			`ix = (int)(xin * bininvx) - mbinxlo - 1;`
			`}`

			`if(yin >= yprd) {`
			`iy = (int)((yin - yprd) * bininvy) + nbiny - mbinylo;`
			`} else if(yin >= 0.0) {`
			`iy = (int)(yin * bininvy) - mbinylo;`
			`} else {`
			`iy = (int)(yin * bininvy) - mbinylo - 1;`
			`}`

			`if(zin >= zprd) {`
			`iz = (int)((zin - zprd) * bininvz) + nbinz - mbinzlo;`
			`} else if(zin >= 0.0) {`
			`iz = (int)(zin * bininvz) - mbinzlo;`
			`} else {`
			`iz = (int)(zin * bininvz) - mbinzlo - 1;`
			`}`

			`return (iz * mbiny * mbinx + iy * mbinx + ix + 1);`
			`}`

			`void binatoms(Atom *atom)`
			`{`
			`int nall = atom->Nlocal + atom->Nghost;`
			`int resize = 1;`

			`while(resize > 0) {`
			`resize = 0;`

			`for(int i = 0; i < mbins; i++) {`
			`bincount[i] = 0;`
			`}`

			`for(int i = 0; i < nall; i++) {`
Simplify macros for data structure access. Still segvaults for AoS. 2021-03-23 09:26:41 +01:00			`int ibin = coord2bin(atom_x(i), atom_y(i), atom_z(i));`
Introduce modular version. 2020-08-18 14:27:28 +02:00
			`if(bincount[ibin] < atoms_per_bin) {`
			`int ac = bincount[ibin]++;`
			`bins[ibin * atoms_per_bin + ac] = i;`
			`} else {`
			`resize = 1;`
			`}`
			`}`

			`if(resize) {`
			`free(bins);`
			`atoms_per_bin *= 2;`
			`bins = (int) malloc(mbins atoms_per_bin * sizeof(int));`
			`}`
			`}`
			`}`