render percentage, new test scene but currently buggy

src/consts.rs

@@ -4,8 +4,10 @@ pub const COLOR_CHANNELS: usize = 4;
 
 pub const EPSILON: f64 = 1. / 1024.;
 pub const LIGHT_EPSILON: f64 = 1. / 512.;
-pub const MAX_DIST: f64 = 16.;
+//pub const MAX_DIST: f64 = 16.;
+pub const MAX_DIST: f64 = 32.;
 pub const MAX_STEPS: u32 = 1024;
+//pub const MAX_STEPS: u32 = u32::MAX;
 
 pub const DIST_FIX_CORRECTION: f64 = 0.5;
 pub const DIST_CORRECTION: f64 = 3.;
@@ -35,8 +37,10 @@ pub const RAYS_PER_PIXEL: usize = 500;
 //pub const MAX_BOUNCES: u32 = 8;
 pub const MAX_BOUNCES: u32 = 10;
 
+//pub const THREAD_COUNT: usize = 1;
 pub const THREAD_COUNT: usize = 12;
-pub const SLICES_PER_THREAD: usize = 4;
+pub const SLICES_PER_THREAD: usize = 16;
+pub const REPORT_STATUS: bool = true;
 
 pub const UP: Vec3 = Y;
 pub const RIGHT: Vec3 = X;

src/main.rs

@@ -9,6 +9,7 @@ use crate::consts::*;
 use crate::structs::*;
 use crate::material::*;
 use image::{ColorType, ImageFormat};
+use crate::light::Light;
 
 fn default_cam() -> Cam {
     Cam::new_pointing(Y*3. - X*5., O, 0.5)
@@ -64,6 +65,23 @@ fn default_scene2() -> Scene {
     Scene::new(Union::new(Union::new(sphere, Union::new(wall, backwall)), Union::new(light, mirror)))
 }
 
+fn default_scene3() -> Scene {
+    //TODO fix this scene
+    let s1 = WithMaterial::new(Sphere::new_xyz(4., 0., 0., 1.), WHITE);
+    let s2 = WithMaterial::new(Sphere::new_xyz(3., 1., 1., 0.5), GREEN);
+    let navion = WithMaterial::new(Plane::new_xyz(0., 1., -1., 3.), BLUE);
+    let backwall = WithMaterial::new(Plane::new_xyz(-1., -1., -0.5, 8.), RED);
+    let boiboite = Cuboid::new_xyz(4., 1.1, -1.1, 0.5, 0.275, 0.275);
+    let decal = AffineTransform::new_translate(boiboite, Vec3::new(-0.25, 0., 0.5));
+    let nope = Exclusion::new(s1, Sphere::new_xyz(3.75, 0.75, 0.75, 1.));
+    let walls = Union::new(navion, backwall);
+    let spheres = Union::new(AffineTransform::new_linear(nope, scale(0.75)), s2);
+    let scene = Union::new(spheres, Union::new(walls, decal));
+    let light = WithMaterial::new(Plane::new_xyz(0., -1., 0., 8.), BRIGHT_AF_LIGHTSOURCE);
+    let scene = WithLight::new_one(scene, Light::new(Y*3.-X*5., ColorVec::new([2., 3., 4., 0.])));
+    Scene::new(Union::new(scene, light))
+}
+
 fn main() {
     // get scene and camera
     let scene = default_scene2();

src/material.rs

@@ -71,6 +71,12 @@ pub const STRONG_LIGHTSOURCE: Material = Material::new_from_diagonal(
     Stop
 );
 
+pub const BRIGHT_AF_LIGHTSOURCE: Material = Material::new_from_diagonal(
+    ColorVec::new([25., 25., 25., 0.]),
+    COLOR_ZERO,
+    Stop
+);
+
 pub const UV_LIGHTSOURCE: Material = Material::new_from_diagonal(
     ColorVec::new_one(3),
     ColorVec::new([0.25, 0.25, 0.25, 1.]),

src/object/exclusion.rs

@@ -0,0 +1,32 @@
+use crate::object::Obj;
+use crate::light::Light;
+use crate::structs::Vec3;
+use std::vec;
+use crate::material::Material;
+
+#[derive(Debug, Copy, Clone, PartialEq)]
+pub struct Exclusion<A: Obj, B: Obj> {
+    a: A,
+    b: B
+}
+
+impl<A: Obj, B: Obj> Exclusion<A, B> {
+    pub fn new(a: A, b: B) -> Exclusion<A, B> {
+        Exclusion { a, b }
+    }
+}
+
+impl<A: Obj, B: Obj> Obj for Exclusion<A, B> {
+    fn distance_to(&self, point: Vec3) -> f64 {
+        f64::max(self.a.distance_to(point), -self.b.distance_to(point))
+    }
+    fn material_at(&self, point: Vec3) -> Material {
+        self.a.material_at(point)
+    }
+    fn get_lights(&self) -> vec::Vec<Light> {
+        self.a.get_lights()
+    }
+    fn node_count(&self) -> u32 {
+        self.a.node_count() + self.b.node_count() + 1
+    }
+}

src/object/intersection.rs

@@ -20,13 +20,6 @@ impl<A: Obj, B: Obj> Obj for Intersection<A, B> {
     fn distance_to(&self, point: Vec3) -> f64 {
         f64::max(self.a.distance_to(point), self.b.distance_to(point))
     }
-    fn normal_at(&self, point: Vec3) -> Vec3 {
-        if self.a.distance_to(point) > self.b.distance_to(point) {
-            self.a.normal_at(point)
-        } else {
-            self.b.normal_at(point)
-        }
-    }
     fn material_at(&self, point: Vec3) -> Material {
         if self.a.distance_to(point) > self.b.distance_to(point) {
             self.a.material_at(point)

src/object/mod.rs

@@ -9,6 +9,7 @@ mod sphere;
 mod plane;
 mod union;
 mod intersection;
+mod exclusion;
 mod cuboid;
 mod cylinder;
 mod torus;
@@ -36,7 +37,9 @@ pub trait Obj: Send + Sync {
     fn get_lights(&self) -> Vec<Light> {
         Vec::new()
     }
-    fn node_count(&self) -> u32 { 1 }
+    fn node_count(&self) -> u32 {
+        1
+    }
 }
 
 impl<T: Obj> Obj for &T {
@@ -61,6 +64,7 @@ pub use sphere::Sphere;
 pub use plane::Plane;
 pub use union::Union;
 pub use intersection::Intersection;
+pub use exclusion::Exclusion;
 pub use cuboid::Cuboid;
 pub use cylinder::Cylinder;
 pub use torus::Torus;

src/object/transform.rs

@@ -63,7 +63,7 @@ impl<T: Obj + Clone> Obj for AffineTransform<T> {
         self.obj.distance_to(self.apply_rev(point))
     }
     fn normal_at(&self, point: Vec3) -> Vec3 {
-        self.apply_fwd(self.obj.normal_at(self.apply_rev(point)))
+        self.apply_fwd(self.obj.normal_at(self.apply_rev(point))).unit()
     }
     fn material_at(&self, point: Vec3) -> Material {
         self.obj.material_at(self.apply_rev(point))

src/structs/cam.rs

@@ -7,6 +7,7 @@ use std::f64::consts::PI;
 use rand::prelude::*;
 use crossbeam_channel::unbounded;
 use std::ops::{Mul, Add, Sub};
+use std::io::Write;
 
 #[derive(Debug, Copy, Clone, PartialEq)]
 pub struct Cam {
@@ -99,10 +100,10 @@ fn shoot_ray_at<T: Obj>(scene: &T, pos: Vec3, dest: Vec3) -> bool {
         let point = ray.point(dist);
         let sd = scene.distance_to(point);
         let dd = dest.distance_to(point);
-        if sd < 0. {
+        if sd <= 0. {
             return false;
         }
-        if dd < sd {
+        if dd <= sd {
             return true;
         }
         dist += if sd < EPSILON { EPSILON } else { sd };
@@ -121,6 +122,12 @@ impl Cam {
     }
 
     pub fn render_singlethreaded<T: Obj>(&self, scene: &T) -> Image {
+        let mut stderr = std::io::stderr();
+        if REPORT_STATUS {
+            stderr.write_all(format!("Rendering... 0/{} rows (0.00%)", IMG_HEIGHT).as_bytes()).unwrap();
+            stderr.flush();
+        }
+
         let lights = scene.get_lights();
         let mut pixels = [0; IMG_BYTE_SIZE];
         for y in 0..IMG_HEIGHT {
@@ -128,7 +135,18 @@ impl Cam {
                 let field_pos = (x + y*IMG_WIDTH) * 3;
                 self.render_single(scene, &lights, x, y, &mut pixels[field_pos..(field_pos+3)]);
             }
+
+            if REPORT_STATUS {
+                stderr.write_all(format!("\x1b[1K\x1b[GRendering... {}/{} rows ({:.2}%)", y+1, IMG_HEIGHT, (y+1) as f64/IMG_HEIGHT as f64).as_bytes());
+                stderr.flush();
+            }
         }
+
+        if REPORT_STATUS {
+            stderr.write_all(format!("\x1b[1K\x1b[GRendering... Done\n").as_bytes());
+            stderr.flush();
+        }
+
         pixels
     }
 
@@ -176,6 +194,7 @@ impl Cam {
             drop(data_tx);
 
             // send the slice data
+            let mut total_slices = 0u32;
             let mut y = 0;
             while y < IMG_HEIGHT {
                 let mut x = 0;
@@ -184,12 +203,23 @@ impl Cam {
                     let h = usize::min(slice_height, IMG_HEIGHT - y);
                     slice_tx.send(Slice { x, y, w, h }).unwrap();
                     x += slice_width;
+
+                    if REPORT_STATUS {
+                        total_slices += 1;
+                    }
                 }
                 y += slice_height;
             }
             drop(slice_tx);
 
             // merge stuff as we get it
+            let mut stderr = std::io::stderr();
+            if REPORT_STATUS {
+                stderr.write_all(format!("Rendering... 0/{} slices (0.00%), 0.00% pixels", total_slices).as_bytes()).unwrap();
+                stderr.flush();
+            }
+            let mut rendered_slices = 0u32;
+            let mut rendered_pixels = 0u64;
             for (slice, data) in data_rx {
                 let data = data.as_slice();
                 for sy in 0..slice.h {
@@ -204,6 +234,19 @@ impl Cam {
                         pixels[pi + 2] = data[si + 2];
                     }
                 }
+
+                if REPORT_STATUS {
+                    rendered_slices += 1;
+                    rendered_pixels += (slice.w*slice.h) as u64;
+                    let pct_slices = rendered_slices as f64 / total_slices as f64 * 100.;
+                    let pct_pixels = rendered_pixels as f64 / (IMG_WIDTH * IMG_HEIGHT) as f64 * 100.;
+                    stderr.write_all(format!("\x1b[1K\x1b[GRendering... {}/{} slices ({:.02}%), {:.02}% pixels", rendered_slices, total_slices, pct_slices, pct_pixels).as_bytes()).unwrap();
+                    stderr.flush();
+                }
+            }
+            if REPORT_STATUS {
+                stderr.write_all(format!("\x1b[1K\x1b[GRendering... Done\n").as_bytes());
+                stderr.flush();
             }
         }).unwrap();
 
@@ -269,7 +312,7 @@ impl Cam {
             match hit {
                 Some(hit) => {
                     i += 1;
-                    pos = hit.pos - dir * EPSILON;
+                    pos = hit.pos + (hit.normal - dir) * EPSILON;
                     match hit.material.surface() {
                         SurfaceType::Stop => break,
                         SurfaceType::Diffuse => {
@@ -281,11 +324,7 @@ impl Cam {
                             let x = r1.cos()*r2.sqrt();
                             let y = r1.sin()*r2.sqrt();
                             let z = (1.-r2).sqrt();
-                            if w.x().abs() < 0.5 {
-                                dir = (u*x + v*y + w*z).unit();
-                            } else {
                             dir = (u*x + v*y + w*z).unit();
-                            }
                         },
                         SurfaceType::Reflective => {
                             dir = dir - hit.normal * (hit.normal * dir) * 2.;