6.1/6.1.Shading with Surface Normals

2025-08-02 02:35:31 +08:00 · 2025-08-02 02:35:31 +08:00 · 3d835bcf63
parent dca286296c
commit 3d835bcf63
2 changed files with 117 additions and 2 deletions
--- a/src/image.rs
+++ b/src/image.rs
@ -10,6 +10,41 @@ impl Color {
    }
 }
 pub fn gen_ray_sphere_normal_ppm_p3(width: i32, height: i32, camera_center: Vec3, viewport_top_left_pixel_center: Vec3, viewport_u_delta: Vec3, viewport_v_delta: Vec3) -> String {
    let mut img_content = format!("P3\n{} {}\n255\n", width, height);
    for j in 0..height {
        if j % 10 == 0 {
            println!("scan line {}/{} ", j + 1, height);
        }
        for i in 0..width {
            // every pixcel's position
            let pixel_center = viewport_top_left_pixel_center + (i as f32 * viewport_u_delta) + (j as f32 * viewport_v_delta);
            // Vector(camera, pixcel)
            let ray_direction = pixel_center - camera_center;
            // ray
            let r = Ray::new(camera_center,  ray_direction);
            /*
             球
             */
            let _sphere_center = Point::new(0.0, 0.0, -1.0);
            let sphere_radius = 0.5;
            // determind color
            let color = ray_color_at_sphere_normal(&r, _sphere_center, sphere_radius);
            // content
            img_content.push_str(color.to_color().as_str());
            img_content.push('\n');
        }
    }
    img_content
 }
 pub fn gen_ray_sphere_ppm_p3(width: i32, height: i32, camera_center: Vec3, viewport_top_left_pixel_center: Vec3, viewport_u_delta: Vec3, viewport_v_delta: Vec3) -> String {
    let mut img_content = format!("P3\n{} {}\n255\n", width, height);
@ -85,9 +120,51 @@ fn hit_sphere(r: &Ray, sphere_center: Point, sphere_radius: f32) -> bool {
 }
 fn hit_sphere_normal(r: &Ray, sphere_center: Point, sphere_radius: f32) -> f32 {
    let a: f32 = r.direction.length_squared();
    let h = r.direction.dot(sphere_center - r.point);
    // let b = -2.0 * r.direction.dot(sphere_center - r.point);
    let c = (sphere_center - r.point).length_squared() - sphere_radius * sphere_radius;
    let discriminant = h*h - a*c;
    // // 两个焦点
    let disc_sqrt = discriminant.sqrt();
    let near = (h - disc_sqrt) / a;
    let far = (h + disc_sqrt) / a;
    // 射线起点可能在球内的情况
    if near >= 0.0 && far >= 0.0 {
        return near.min(far);
    } else if near > 0.0 {
        return near;
    } else if far > 0.0 {
        return far;
    } else {
        return -1.0
    }
 }
 /*
-get color of this ray; background
+ray color functions
 */
 fn ray_color_at_sphere_normal(r: &Ray, sphere_center: Point, sphere_radius: f32) -> Color {
    let t = hit_sphere_normal(r, sphere_center, sphere_radius);
    if t >= 0.0 {
        let inter_point = r.at(t);
        // 单位向量
        let n = inter_point / inter_point.dot(inter_point);
        // 法向量也是 -1～1  +1再x0.5让他落到颜色的区间
        return 0.5 * (n - sphere_center + Point::new(1.0, 1.0, 1.0))
    }
    // v / |v|
    let unit_direction = r.direction / r.direction.length();
    let a = 0.5*(unit_direction.y + 1.0);
    return (1.0-a)*Color::new(1.0, 1.0, 1.0) + a*Color::new(0.5, 0.7, 1.0);
 }
 fn ray_color_at_sphere(r: &Ray, sphere_center: Point, sphere_radius: f32) -> Color {
    // return RED if hit sphere
--- a/src/main.rs
+++ b/src/main.rs
@ -4,7 +4,7 @@ use vec3::{Vec3};
 use point::{Point};
 use ray::{Ray};
-use crate::image::gen_ray_sphere_ppm_p3;
+use crate::image::{gen_ray_sphere_normal_ppm_p3, gen_ray_sphere_ppm_p3};
 mod image;
 mod write_file_util;
@ -19,9 +19,47 @@ fn main() {
    println!("==================================");
    ray_sphere_scene_render();
    println!("==================================");
    ray_sphere_normal_scene_render();
    println!("==================================");
 }
 fn ray_sphere_normal_scene_render() {
    let aspect_ratio = 16.0/9.0;
    let image_width = 400;
    // aleast 1px
    let image_height = ((image_width as f32 / aspect_ratio) as i32).max(1);
    let viewport_height = 2.0;
    let viewport_width = viewport_height * (image_width as f32 / image_height as f32);
    println!("set image({},{}), viewport({},{})", image_width, image_height, viewport_width, viewport_height);
    let viewport_u = Vec3::new(viewport_width, 0.0, 0.0);
    // image x--> right
    //       |
    //       y
    // space: y up , x right , z back, -z front
    let viewport_v = Vec3::new(0.0, -viewport_height, 0.0);
    // width per pix
    let viewport_u_delta = viewport_u / (image_width as f32);
    // height per pix
    let viewport_v_delta = viewport_v / (image_height as f32);
    // camerea position
    let camera_center = Point::new(0.0, 0.0, 0.0);
    // -z  1.0  viewport to camera
    let focal_length = Vec3::new(0.0, 0.0, -1.0);
    // camera position --> viewport center ---> top center --> top left
    let viewport_top_left_pixel = camera_center + focal_length - viewport_u / 2.0 - viewport_v / 2.0;
    // padding 0.5* delta u/v
    let viewport_top_left_pixel_center = viewport_top_left_pixel - viewport_u_delta / 2.0 - viewport_v_delta / 2.0;
    let ppm_content = gen_ray_sphere_normal_ppm_p3(image_width, image_height, camera_center, viewport_top_left_pixel_center, viewport_u_delta, viewport_v_delta);
    write_image(ppm_content, "./target/ray_sphere_normal_scene_render.ppm".to_string())
 }
 fn ray_sphere_scene_render() {
    let aspect_ratio = 16.0/9.0;
    let image_width = 400;