plane.h
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#ifndef RTS_PLANE_H
#define RTS_PLANE_H
#include <iostream>
#include <stim/math/vector.h>
#include "rts/cuda/callable.h"
namespace stim{
template <typename T, int D> class plane;
}
template <typename T, int D>
CUDA_CALLABLE stim::plane<T, D> operator-(stim::plane<T, D> v);
namespace stim{
template <class T, int D = 3>
class plane{
//a plane is defined by a point and a normal
private:
vec<T, D> P; //point on the plane
vec<T, D> N; //plane normal
CUDA_CALLABLE void init(){
P = vec<T, D>(0, 0, 0);
N = vec<T, D>(0, 0, 1);
}
public:
//default constructor
CUDA_CALLABLE plane(){
init();
}
CUDA_CALLABLE plane(vec<T, D> n, vec<T, D> p = vec<T, D>(0, 0, 0)){
P = p;
N = n.norm();
}
CUDA_CALLABLE plane(T z_pos){
init();
P[2] = z_pos;
}
//create a plane from three points (a triangle)
CUDA_CALLABLE plane(vec<T, D> a, vec<T, D> b, vec<T, D> c){
P = c;
N = (c - a).cross(b - a);
if(N.len() == 0) //handle the degenerate case when two vectors are the same, N = 0
N = 0;
else
N = N.norm();
}
template< typename U >
CUDA_CALLABLE operator plane<U, D>(){
plane<U, D> result(N, P);
return result;
}
CUDA_CALLABLE vec<T, D> norm(){
return N;
}
CUDA_CALLABLE vec<T, D> p(){
return P;
}
//flip the plane front-to-back
CUDA_CALLABLE plane<T, D> flip(){
plane<T, D> result = *this;
result.N = -result.N;
return result;
}
//determines how a vector v intersects the plane (1 = intersects front, 0 = within plane, -1 = intersects back)
CUDA_CALLABLE int face(vec<T, D> v){
T dprod = v.dot(N); //get the dot product between v and N
//conditional returns the appropriate value
if(dprod < 0)
return 1;
else if(dprod > 0)
return -1;
else
return 0;
}
//determine on which side of the plane a point lies (1 = front, 0 = on the plane, -1 = back)
CUDA_CALLABLE int side(vec<T, D> p){
vec<T, D> v = p - P; //get the vector from P to the query point p
return face(v);
}
//compute the component of v that is perpendicular to the plane
CUDA_CALLABLE vec<T, D> perpendicular(vec<T, D> v){
return N * v.dot(N);
}
//compute the projection of v in the plane
CUDA_CALLABLE vec<T, D> parallel(vec<T, D> v){
return v - perpendicular(v);
}
CUDA_CALLABLE void decompose(vec<T, D> v, vec<T, D>& para, vec<T, D>& perp){
perp = N * v.dot(N);
para = v - perp;
}
//get both the parallel and perpendicular components of a vector v w.r.t. the plane
CUDA_CALLABLE void project(vec<T, D> v, vec<T, D> &v_par, vec<T, D> &v_perp){
v_perp = v.dot(N);
v_par = v - v_perp;
}
//compute the reflection of v off of the plane
CUDA_CALLABLE vec<T, D> reflect(vec<T, D> v){
//compute the reflection using N_prime as the plane normal
vec<T, D> par = parallel(v);
vec<T, D> r = (-v) + par * 2;
/*std::cout<<"----------------REFLECT-----------------------------"<<std::endl;
std::cout<<str()<<std::endl;
std::cout<<"v: "<<v<<std::endl;
std::cout<<"r: "<<r<<std::endl;
std::cout<<"Perpendicular: "<<perpendicular(v)<<std::endl;
std::cout<<"Parallel: "<<par<<std::endl;*/
return r;
}
CUDA_CALLABLE rts::plane<T, D> operator-()
{
rts::plane<T, D> p = *this;
//negate the normal vector
p.N = -p.N;
return p;
}
//output a string
std::string str(){
std::stringstream ss;
ss<<"P: "<<P<<std::endl;
ss<<"N: "<<N;
return ss.str();
}
///////Friendship
//friend CUDA_CALLABLE rts::plane<T, D> operator- <> (rts::plane<T, D> v);
};
}
//arithmetic operators
//negative operator flips the plane (front to back)
//template <typename T, int D>
#endif