hyporo-cpp/source/applications/periodic/lattice.hpp

205 lines
6.1 KiB
C++

#pragma once
#include "../../hpr/math.hpp"
#include "../../hpr/csg.hpp"
namespace hpr::csg
{
void prints(scalar point)
{
std::cout << point << std::endl;
}
class Lattice : public csg::Shape
{
public:
enum class System
{
Triclinic,
Monoclinic,
Orthorhombic,
Tetragonal,
Rhombohedral,
Hexagonal,
Cubic,
Unknown
};
enum class Type
{
Primitive,
BaseCentered,
BodyCentered,
FaceCentered,
Unknown
};
protected:
vec3 p_lengths;
vec3 p_angles;
Type p_type;
scalar p_radius;
darray<vec3> p_controlPoints;
public:
Lattice() = delete;
Lattice(const vec3& lengths, const vec3& angles, scalar radius, Type type) :
csg::Shape {},
p_lengths {lengths},
p_angles {angles},
p_radius {radius},
p_type {type}
{
generateControlPoints();
darray<csg::Shape> spheres;
for (const auto& point : controlPoints()) {
spheres.push(csg::sphere(point, p_radius));
print(point);
}
p_shape = csg::Compound(spheres).tshape();//csg::fuse({spheres.front()}, spheres.slice(spheres.begin() + 1, spheres.end())).tshape();
}
darray<vec3> controlPoints() const
{
return p_controlPoints;
}
vec3 lengths() const
{
return p_lengths;
}
vec3 angles() const
{
return p_angles;
}
void generateControlPoints()
{
if (p_type == Type::Unknown)
throw std::runtime_error("Unknown type of lattice");
p_controlPoints.resize(14);
//
vec3 ox {1, 0, 0};
vec3 oy {0, 1, 0};
vec3 oz {0, 0, 1};
vec3 ox1 = hpr::rotate(ox, oz, radians(-p_angles[2]));
p_controlPoints.push(vec3{0, 0, 0});
p_controlPoints.push(vec3{0, p_lengths[0], 0});
vec3 t1 = hpr::translate(p_controlPoints.back(), ox1 * p_lengths[1]);
p_controlPoints.push(t1);
p_controlPoints.push(hpr::translate(p_controlPoints.front(), ox1 * p_lengths[1]));
print(t1);
print(ox1);
scalar c1 = cos(radians(p_angles[2])), c2 = cos(radians(p_angles[1])), c3 = cos(radians(p_angles[0]));
scalar D1 = sqrt(mat3(
1, cos(radians(p_angles[2])), cos(radians(p_angles[1])),
cos(radians(p_angles[2])), 1, cos(radians(p_angles[0])),
cos(radians(p_angles[1])), cos(radians(p_angles[0])), 1).det());
scalar volume = 1. / 6. * p_lengths[0] * p_lengths[1] * p_lengths[2] *
D1;
scalar s1 = sqrt(std::pow(p_lengths[0], 2) + std::pow(p_lengths[1], 2) - 2 *
p_lengths[0] * p_lengths[1] * cos(radians(p_angles[2])));
scalar s2 = sqrt(std::pow(p_lengths[1], 2) + std::pow(p_lengths[2], 2) - 2 *
p_lengths[1] * p_lengths[2] * cos(radians(p_angles[1])));
scalar s3 = sqrt(std::pow(p_lengths[0], 2) + std::pow(p_lengths[2], 2) - 2 *
p_lengths[0] * p_lengths[2] * cos(radians(p_angles[0])));
scalar area = 1. / 2. * p_lengths[0] * p_lengths[1] *
sqrt(mat2{1, cos(radians(p_angles[2])), cos(radians(p_angles[2])), 1}.det());
scalar h1 = 3 * volume / area;
scalar a1 = asin(h1 / p_lengths[2]);
scalar sh1 = sqrt(std::pow(p_lengths[2], 2) - std::pow(h1, 2));
scalar sh2 = p_lengths[2] * cos(radians(p_angles[0]));
scalar a2 = acos(sh2 / sh1);
vec3 ox2 = hpr::rotate(ox, oy, a1);
if (!std::isnan(a2))
ox2 = hpr::rotate(ox2, oz, a2);
print(ox2);
for (auto n = 0; n < 4; ++n)
p_controlPoints.push(hpr::translate(p_controlPoints[n], ox2 * p_lengths[2]));
/*p_controlPoints.push(vec3{p_lengths[0], p_lengths[1], 0});
p_controlPoints.push(vec3{p_lengths[0], 0, 0});
p_controlPoints.push(vec3{0, 0, p_lengths[2]});
p_controlPoints.push(vec3{0, p_lengths[1], p_lengths[2]});
p_controlPoints.push(vec3{p_lengths[0], p_lengths[1], p_lengths[2]});
p_controlPoints.push(vec3{p_lengths[0], 0, p_lengths[2]});
// central points on base faces
if (p_type == Type::BaseCentered || p_type == Type::FaceCentered)
{
for (int n = 0; n < 2; ++n)
{
vec3 center;
for (int k = 0; k < 4; ++k)
center += p_controlPoints[k + 4 * n];
p_controlPoints.push(center * 0.25);
}
}
// central point (center of mass)
if (p_type == Type::BodyCentered)
{
vec3 center;
for (const auto& point : p_controlPoints)
center += point;
p_controlPoints.push(center / p_controlPoints.size());
}
// central points on side faces
if (p_type == Type::FaceCentered)
{
for (int n = 0; n < 3; ++n)
{
vec3 center;
for (int k = 0; k < 2; ++k)
{
center += p_controlPoints[n + k];
center += p_controlPoints[n + k + 4];
}
p_controlPoints.push(center * 0.25);
}
vec3 center;
for (int n = 0; n < 2; ++n)
{
center += p_controlPoints[n * 3];
center += p_controlPoints[4 + n * 3];
}
p_controlPoints.push(center * 0.25);
}
mat4 trans = mat4::identity();
vec3 ox {1, 0, 0};
vec3 oy {0, 1, 0};
vec3 oz {0, 0, 1};
int n = 0;
for (auto& point : p_controlPoints)
{
if (n == 0 || n == 3)
{
++n;
continue;
}
trans.row(3, vec4(point, 0));
trans = hpr::rotate(trans, oz, -radians(90 - p_angles[2]));
if (n >= 4 && n <= 7)
{
trans = hpr::rotate(trans, ox, -radians(90 - p_angles[1]));
trans = hpr::rotate(trans, oy, -radians(90 - p_angles[0]));
}
point = vec3(trans.row(3)[0], trans.row(3)[1], trans.row(3)[2]);
++n;
}*/
}
};
}