#pragma once
#include <vector>
namespace cgv {
namespace data {
template <typename Pnt, typename Idx = int>
class grid : public std::vector<std::vector<Idx> >
{
public:
typename decltype(min_pnt[0]) Crd;
typename decltype(max_pnt-min_pnt) Vec;
std::size_t dim[3];
Crd rmax;
Crd rmax_sqr;
Crd rmax_estimate_factor;
protected:
Vec scale;
Vec extent;
Vec cell_extent;
Pnt min_pnt, max_pnt;
void init() {
clear();
resize(get_size());
}
void compute_scales() {
extent = max_pnt-min_pnt;
for (int c=0; c<3; ++c) {
scale[c] = dim[c]/extent[c];
cell_extent[c] = extent[c]/dim[c];
}
}
public:
grid(Idx dim = 20) { set_dim(dim); init(); }
grid(Idx dimx, Idx dimy, Idx dimz) { set_dim(dimx,dimy,dimz); init(); }
void clear() {
std::vector<std::vector<Idx> >::clear();
min_pnt = Pnt(-1,-1,-1);
max_pnt = Pnt(1,1,1);
}
bool is_empty() const { return std::vector<std::vector<Idx> >::empty(); }
void set_dim(Cnt dim) { set_dim(dim,dim,dim); }
void set_dim(Cnt dimx, Cnt dimy, Cnt dimz) {
dim[0] = dimx;
dim[1] = dimy;
dim[2] = dimz;
init();
compute_scales();
}
void set_box(const Pnt& _min_pnt, const Pnt& _max_pnt) {
min_pnt = _min_pnt;
max_pnt = _max_pnt;
compute_scales();
}
template <typename Func>
void compute_box(Idx nr_points, const Func& pnts) {
min_pnt = max_pnt = pnts(0);
for (Idx i=1; i<nr_points; ++i) {
for (int c=0; c<3; ++c) {
if (pnts(i)[c] < min_pnt[c])
min_pnt[c] = pnts(i)[c];
if (pnts(i)[c] > max_pnt[c])
max_pnt[c] = pnts(i)[c];
}
}
compute_scales();
}
/// before calling the build function, ensure that the bounding box has been set with set_box or computed with compute_box
template <typename Func>
void build(Idx nr_points, const Func& pnts) {
init();
rmax = (Crd) (rmax_estimate_factor*sqrt(2*(extent[0]*(extent[1]+extent[2])+extent[1]*extent[2])/nr_points));
rmax_sqr = rmax*rmax;
cout << "rmax = " << rmax << endl;
set_dim((Idx)(extent[0]/rmax), (Idx)(extent[1]/rmax), (Idx)(extent[2]/rmax));
for (Idx i=0; i<nr_points; ++i)
insert(pnts(i), i);
}
Idx get_size() const {
return dim[0]*dim[1]*dim[2];
}
template <typename Jdx>
Idx get_index(Jdx *ci) const {
return (ci[2]*dim[1]+ci[1])*dim[0]+ci[0];
}
Idx get_index(const Pnt& p) const {
Idx ci[3];
for (int c = 0; c < 3; ++c) {
ci[c] = (Idx) (scale[c]*(p[c]-min_pnt[c]));
if (ci[c] >= (Idx)dim[c])
ci[c] = dim[c]-1;
}
return get_index(ci);
}
template <typename Jdx>
void split_index(Idx idx, Jdx* ci) const {
Idx n = dim[0]*dim[1];
ci[2] = (Jdx)(idx / n);
idx -= n*ci[2];
ci[1] = (Jdx)(idx/dim[0]);
ci[0] = (Jdx)(idx-dim[0]*ci[1]);
}
void put_grid_cell(Idx idx, const Pnt& _min_pnt, const Pnt& _max_pnt) const {
Idx ci[3];
split_index(idx, ci);
for (int c=0; c<3; ++c)
_min_pnt[c] = ci[c]/scale[c] + min_pnt[c];
_max_pnt = _min_pnt+cell_extent;
}
void insert(const Pnt& p, Idx i) {
Idx ci = get_index(p);
if (ci >= size()) {
std::cerr << "hit not available cell " << ci << endl;
return;
}
at(ci).push_back(i);
}
void add_neighbors(Idx pi, const Pnt& p, Idx ci, const Func& pnts, vector<Idx>& N) const {
for (Idx i=0; i<at(ci).size(); ++i) {
Idx ni = at(ci)[i];
if (ni != pi) {
if (sqr_length(pnts(ni)-p) < rmax_sqr)
N.push_back(ni);
}
}
}
template <typename Func>
void extract_neighbors(Idx i, const Func& pnts, vector<Idx>& N) const
{
static const int d[3*26] = {
1,0,0,
0,1,0,
0,0,1,
-1,0,0,
0,-1,0,
0,0,-1,
1,1,0,
0,1,1,
1,0,1,
-1,1,0,
0,-1,1,
-1,0,1,
1,-1,0,
0,1,-1,
1,0,-1,
-1,-1,0,
0,-1,-1,
-1,0,-1,
1,1,1,
-1,1,1,
1,-1,1,
-1,-1,1,
1,1,-1,
-1,1,-1,
1,-1,-1,
-1,-1,-1
};
const Pnt& p = pnts(i);
Idx ci = get_index(p);
add_neighbors(i, p, ci, N);
for (int j=0; j<26; ++j) {
Idx cj = ci+d[3*j]+dim[0]*(d[3*j+1]+dim[1]*d[3*j+2]);
if (cj >= 0 && cj < (Idx)size())
add_neighbors(i, p, cj, N);
}
}
};
}
}