Renderer/src/hittable.rs

use super::Point3;
use super::Ray;
use super::Vec3;

pub struct HitRecord {
    pub p: Point3,
    pub normal: Vec3,
    pub t: f64,
    front_face: bool,
}

pub struct Sphere {
    center: Point3,
    radius: f64,
}

pub trait Hittable: Sync+Send {
    fn hit(&self, r: &Ray, t_min: f64, t_max: f64, rec: &mut HitRecord) -> bool;
}

impl HitRecord {
    fn set_face_normal(&mut self, r: &Ray, outward_normal: Vec3) {
        self.front_face = Vec3::dot(r.direction(), outward_normal) < 0.0;
        if self.front_face {
            self.normal = outward_normal;
        } else {
            self.normal = (-1.0) * outward_normal;
        }
    }

    pub fn new(p: Point3, normal: Vec3, t: f64, front_face: bool) -> Self {
        HitRecord {
            p: p,
            normal: normal,
            t: t,
            front_face: front_face,
        }
    }

    pub fn empty() -> Self {
        Self::new(
            Point3::new(0.0, 0.0, 0.0),
            Vec3::new(0.0, 0.0, 0.0),
            0.0,
            false,
        )
    }
}

impl Sphere {
    pub fn new(cen: Point3, r: f64) -> Self {
        Sphere {
            center: cen,
            radius: r,
        }
    }
}

impl Hittable for Sphere {
    fn hit(&self, r: &Ray, t_min: f64, t_max: f64, rec: &mut HitRecord) -> bool {
        let oc = r.origin() - self.center;
        let a = r.direction().length_squared(); // gleiches Ergebnis wie Skalarprodukt
        let half_b = Vec3::dot(oc, r.direction());
        let c = oc.length_squared() - self.radius * self.radius;

        let discriminant = half_b * half_b - a * c;
        if discriminant < 0.0 {
            return false;
        }

        let sqrtd = discriminant.sqrt();

        let root = (-half_b - sqrtd) / a;
        let normal = (r.at(root) - self.center) / self.radius;
        if root < t_min || t_max < root || Vec3::dot(normal, r.direction()) > 0.0 {
            let root2 = (-half_b + sqrtd) / a;
            let normal = (r.at(root2) - self.center) / self.radius;
            if root2 < t_min || t_max < root || Vec3::dot(normal, r.direction()) > 0.0 {
                return false;
            }
        }

        rec.t = root;
        rec.p = r.at(rec.t);
        let outward_normal = (rec.p - self.center) / self.radius;
        rec.set_face_normal(r, outward_normal);

        return true;
    }
}
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`use super::Point3;`
			`use super::Ray;`
			`use super::Vec3;`

			`pub struct HitRecord {`
Schwarze Oberfläche 2022-05-18 17:49:46 +02:00			`pub p: Point3,`
Multisphärisch 2022-05-04 18:21:48 +02:00			`pub normal: Vec3,`
			`pub t: f64,`
			`front_face: bool,`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`}`

			`pub struct Sphere {`
			`center: Point3,`
			`radius: f64,`
			`}`

Multithreading 2022-06-01 17:59:25 +02:00			`pub trait Hittable: Sync+Send {`
Multisphärisch 2022-05-04 18:21:48 +02:00			`fn hit(&self, r: &Ray, t_min: f64, t_max: f64, rec: &mut HitRecord) -> bool;`
			`}`

			`impl HitRecord {`
			`fn set_face_normal(&mut self, r: &Ray, outward_normal: Vec3) {`
			`self.front_face = Vec3::dot(r.direction(), outward_normal) < 0.0;`
			`if self.front_face {`
			`self.normal = outward_normal;`
			`} else {`
Antialiasinggit status1! 2022-05-11 18:38:30 +02:00			`self.normal = (-1.0) * outward_normal;`
Multisphärisch 2022-05-04 18:21:48 +02:00			`}`
			`}`

			`pub fn new(p: Point3, normal: Vec3, t: f64, front_face: bool) -> Self {`
			`HitRecord {`
			`p: p,`
			`normal: normal,`
			`t: t,`
			`front_face: front_face,`
			`}`
			`}`

			`pub fn empty() -> Self {`
Antialiasinggit status1! 2022-05-11 18:38:30 +02:00			`Self::new(`
			`Point3::new(0.0, 0.0, 0.0),`
			`Vec3::new(0.0, 0.0, 0.0),`
			`0.0,`
			`false,`
			`)`
Multisphärisch 2022-05-04 18:21:48 +02:00			`}`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`}`

			`impl Sphere {`
Multisphärisch 2022-05-04 18:21:48 +02:00			`pub fn new(cen: Point3, r: f64) -> Self {`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`Sphere {`
			`center: cen,`
			`radius: r,`
			`}`
			`}`
			`}`

			`impl Hittable for Sphere {`
Multisphärisch 2022-05-04 18:21:48 +02:00			`fn hit(&self, r: &Ray, t_min: f64, t_max: f64, rec: &mut HitRecord) -> bool {`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`let oc = r.origin() - self.center;`
			`let a = r.direction().length_squared(); // gleiches Ergebnis wie Skalarprodukt`
Multisphärisch 2022-05-04 18:21:48 +02:00			`let half_b = Vec3::dot(oc, r.direction());`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`let c = oc.length_squared() - self.radius * self.radius;`

Multisphärisch 2022-05-04 18:21:48 +02:00			`let discriminant = half_b * half_b - a * c;`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`if discriminant < 0.0 {`
			`return false;`
			`}`

			`let sqrtd = discriminant.sqrt();`

Multisphärisch 2022-05-04 18:21:48 +02:00			`let root = (-half_b - sqrtd) / a;`
hit check normal vec angle 2022-06-01 16:49:39 +02:00			`let normal = (r.at(root) - self.center) / self.radius;`
			`if root < t_min \|\| t_max < root \|\| Vec3::dot(normal, r.direction()) > 0.0 {`
Multisphärisch 2022-05-04 18:21:48 +02:00			`let root2 = (-half_b + sqrtd) / a;`
hit check normal vec angle 2022-06-01 16:49:39 +02:00			`let normal = (r.at(root2) - self.center) / self.radius;`
			`if root2 < t_min \|\| t_max < root \|\| Vec3::dot(normal, r.direction()) > 0.0 {`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00			`return false;`
			`}`
			`}`

			`rec.t = root;`
			`rec.p = r.at(rec.t);`
Multisphärisch 2022-05-04 18:21:48 +02:00			`let outward_normal = (rec.p - self.center) / self.radius;`
			`rec.set_face_normal(r, outward_normal);`
Viel Stuff, hittable objects auslagern 2022-04-27 18:27:07 +02:00
			`return true;`
			`}`
			`}`