49 lines
1.1 KiB
C++
49 lines
1.1 KiB
C++
#ifndef SPHERE_H
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#define SPHERE_H
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#include "hittable.h"
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#include "vec3.h"
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class sphere : public hittable {
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public:
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sphere() {}
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sphere(point3 cen, double r, shared_ptr<material> m) : center(cen), radius(r), mat_ptr(m) {};
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virtual bool hit(
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const ray& r, double t_min, double t_max, hit_record& rec) const override;
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public:
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point3 center;
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double radius;
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shared_ptr<material> mat_ptr;
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};
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bool sphere::hit(const ray& r, double t_min, double t_max, hit_record& rec) const {
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vec3 oc = r.origin() - center;
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auto a = r.direction().length_squared();
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auto half_b = dot(oc, r.direction());
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auto c = oc.length_squared() - radius*radius;
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auto discriminant = half_b*half_b - a*c;
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if (discriminant < 0) return false;
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auto sqrtd = sqrt(discriminant);
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// Find the nearest root that lies in the acceptable range.
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auto root = (-half_b - sqrtd) / a;
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if (root < t_min || t_max < root) {
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root = (-half_b + sqrtd) / a;
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if (root < t_min || t_max < root)
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return false;
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}
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rec.t = root;
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rec.p = r.at(rec.t);
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vec3 outward_normal = (rec.p - center) / radius;
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rec.set_face_normal(r, outward_normal);
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rec.mat_ptr = mat_ptr;
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return true;
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}
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#endif
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