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//
// Created by Keuin on 2022/4/11.
//
#ifndef RT_VEC_H
#define RT_VEC_H
#include <cmath>
#include <random>
#include <ostream>
#include <cassert>
#include <algorithm>
static inline bool eq(int a, int b) {
return a == b;
}
static inline bool eq(long long a, long long b) {
return a == b;
}
static inline bool eq(double a, double b) {
// FIXME broken on large values
// https://randomascii.wordpress.com/2012/02/25/comparing-floating-point-numbers-2012-edition/
// https://stackoverflow.com/a/253874/14332799
const double c = a - b;
return c <= 1e-14 && c >= -1e-14;
}
// 3-dim vector
template<typename T>
struct vec3 {
T x;
T y;
T z;
static vec3 zero() {
return vec3{0, 0, 0};
}
static vec3 one() {
return vec3{1, 1, 1};
}
bool is_zero() const {
#define EPS (1e-8)
return x >= -EPS && y >= -EPS && z >= -EPS && x <= EPS && y <= EPS && z <= EPS;
#undef EPS
}
bool is_one() const {
return (*this - vec3::one()).is_zero();
}
vec3 operator+(const vec3 &b) const {
return vec3{.x=x + b.x, .y=y + b.y, .z=z + b.z};
}
vec3 operator-() const {
return vec3{.x = -x, .y = -y, .z = -z};
}
vec3 operator-(const vec3 &b) const {
return *this + (-b);
}
bool operator==(const vec3 b) const {
return eq(x, b.x) && eq(y, b.y) && eq(z, b.z);
}
// dot product (aka inner product, or scalar product, producing a scalar)
T dot(const vec3 &b) const {
return x * b.x + y * b.y + z * b.z;
}
// cross product (aka outer product, or vector product, producing a vector)
vec3 cross(const vec3 &b) const {
return vec3{.x=y * b.z - z * b.y, .y=z * b.x - x * b.z, .z=x * b.y - y * b.x};
}
// Multiply with b on every dimension.
vec3 scale(const vec3 &b) const {
return vec3{.x=x * b.x, .y=y * b.y, .z=z * b.z};
}
// norm value
double norm(const int level = 2) const {
if (level == 2) {
return std::abs(sqrt(x * x + y * y + z * z));
} else if (level == 1) {
return std::abs(x) + std::abs(y) + std::abs(z);
} else {
return powl(powl(x, level) + powl(y, level) + powl(z, level), 1.0 / level);
}
}
// Squared module
T mod2() const {
return x * x + y * y + z * z;
}
vec3 unit_vec() const {
return *this * (1.0 / norm());
}
// If all the three float-point scalars are finite real number.
bool valid() const {
return std::isfinite(x) && std::isfinite(y) && std::isfinite(z);
}
// Determine if this vector is parallel with another one.
bool parallel(const vec3 &other) const {
const auto dt = dot(other);
const auto dot2 = dt * dt;
const auto sqlp = mod2() * other.mod2(); // squared length product
const auto d = dot2 - sqlp;
return d > -1e-6 && d < 1e-6;
}
// Get the reflected vector. Current vector is the normal vector (length should be 1), v is the incoming vector.
vec3 reflect(const vec3 &v) const {
assert(fabs(mod2() - 1.0) < 1e-8);
return v - (2.0 * dot(v)) * (*this);
}
};
// print to ostream
template<typename T>
inline std::ostream &operator<<(std::ostream &out, const vec3<T> &vec) {
return out << "vec3[x=" << vec.x << ", y=" << vec.y << ", z=" << vec.z << ']';
}
// product vec3 by a scalar, with fp assertions
template<
typename T,
typename S,
typename = typename std::enable_if<std::is_arithmetic<S>::value, S>::type
>
inline vec3<T> operator*(const vec3<T> &vec, const S &b) {
if (std::is_floating_point<S>::value) {
assert(std::isfinite(b));;
}
return vec3<T>{.x=(T) (vec.x * b), .y=(T) (vec.y * b), .z=(T) (vec.z * b)};
}
// product vec3 by a scalar, with fp assertions
template<
typename T,
typename S
>
inline vec3<T> operator*(const S &b, const vec3<T> &vec) {
if (std::is_floating_point<S>::value) {
assert(std::isfinite(b));
}
return vec3<T>{.x=(T) (vec.x * b), .y=(T) (vec.y * b), .z=(T) (vec.z * b)};
}
// product vec3 by the inversion of a scalar (div by a scalar), with fp assertions
template<
typename T,
typename S,
typename = typename std::enable_if<std::is_arithmetic<S>::value, S>::type
>
inline vec3<T> operator/(const vec3<T> &vec, const S &b) {
if (std::is_floating_point<S>::value) {
assert(std::isfinite(b));
assert(b != 0);
}
return vec3<T>{.x=(T) (vec.x / b), .y=(T) (vec.y / b), .z=(T) (vec.z / b)};
}
// scalar product (inner product)
template<typename T>
inline T dot(const vec3<T> &a, const vec3<T> &b) {
return a.dot(b);
}
// vector product (outer product)
template<typename T>
inline vec3<T> cross(const vec3<T> &a, const vec3<T> &b) {
return a.cross(b);
}
// 3-dim vector (int)
using vec3i = vec3<int>;
// 3-dim vector (long long)
using vec3l = vec3<long long>;
// 3-dim vector (float)
using vec3f = vec3<float>;
// 3-dim vector (double)
using vec3d = vec3<double>;
// random unit vector generator
template<typename T>
class rand_vec_gen {
std::mt19937_64 mt;
std::uniform_real_distribution<T> uni{-1.0, 1.0};
public:
rand_vec_gen() = delete;
explicit rand_vec_gen(uint64_t seed) : mt{seed} {}
// Get a random vector whose length is in [0, 1]
inline vec3<T> range01() {
while (true) {
const auto x = uni(mt), y = uni(mt), z = uni(mt);
const auto vec = vec3<T>{.x=x, .y=y, .z=z};
if (vec.mod2() <= 1.0) return vec.unit_vec();
}
}
// Get a random real number in range [0, 1].
inline T range01_scalar() {
return uni(mt);
};
// Get a unit vector with random direction.
inline vec3<T> normalized() {
return range01().unit_vec();
}
// Get a random vector whose length is in [0, 1] and
// has a direction difference less than 90 degree with given vector.
inline vec3<T> hemisphere(vec3<T> &vec) {
const auto v = range01();
if (dot(v, vec) > 0) return v;
return -v;
}
};
using random_uv_gen_3d = rand_vec_gen<double>;
#endif //RT_VEC_H
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