snoopy/src/main.cpp

#include "rtweekend.h"

#include "hittable_list.h"
#include "sphere.h"
#include "colour.h"
#include "camera.h"

#include <iostream>

const double ASPECT_RATIO = 16.0 / 9.0;
const int WIDTH = 384;
const int HEIGHT = static_cast<int>(WIDTH / ASPECT_RATIO);
const int SAMPLES_PER_PIXEL = 100;
const int MAX_DEPTH = 50;

colour ray_colour(const ray& r, const hittable& world, int depth)
{
    hit_record rec;
    if (depth <= 0)
    {
        return colour(0,0,0);
    }

    if (world.hit(r, 0, infinity, rec))
    {
        point3 target = rec.p + rec.normal + random_in_unit_sphere();
        return 0.5 * ray_colour(ray(rec.p, target - rec.p), world, depth-1);
    }

    vec3 unit_direction = unit_vector(r.direction());
    auto t = 0.5 * (unit_direction.y() + 1.0);

    auto a = colour(0.5, 0.6, 0.7);
    auto b = colour(1.0, 1.0, 1.0);

    return lerp(a, b, t);
}

int main()
{
    std::cout << "P3\n" << WIDTH << ' ' << HEIGHT << "\n255\n";

    auto viewport_height = 2.0;
    auto viewport_width = ASPECT_RATIO * viewport_height;
    auto focal_length = 1.0;

    auto origin = point3(0, 0, 0);
    auto horizontal = vec3(viewport_width, 0, 0);
    auto vertical = vec3(0, viewport_height, 0);
    auto lower_left_corner = origin - horizontal/2 - vertical/2 - vec3(0,0,focal_length);

    hittable_list world;
    world.add(make_shared<sphere>(point3(0,0,-1), 0.5));
    world.add(make_shared<sphere>(point3(0,-100.5,-1), 100));

    camera cam;

    for (int j = HEIGHT - 1; j >= 0; --j)
    {
        std::cerr << "\rScanlines remaining: " << j << ' ' << std::flush;
        for (int i = 0; i < WIDTH; ++i)
        {
            colour pixel_colour(0,0,0);

            for (int s = 0; s < SAMPLES_PER_PIXEL; ++s)
            {
                auto u = (i + random_double()) / (WIDTH-1);
                auto v = (j + random_double()) / (HEIGHT-1);
                ray r = cam.get_ray(u, v);
                pixel_colour += ray_colour(r, world, MAX_DEPTH);
            }

            write_colour(std::cout, pixel_colour, SAMPLES_PER_PIXEL);
        }
    }

    std::cerr << "\nDone." << std::endl;
}
add hittable world 2020-06-06 19:28:30 +02:00			`#include "rtweekend.h"`

			`#include "hittable_list.h"`
			`#include "sphere.h"`
add vec3 and colour 2020-06-01 02:49:50 +02:00			`#include "colour.h"`
add camera + multisampling 2020-06-06 22:11:09 +02:00			`#include "camera.h"`
add vec3 and colour 2020-06-01 02:49:50 +02:00
initial commit 2020-06-01 00:52:34 +02:00			`#include <iostream>`

add ray 2020-06-03 02:56:59 +02:00			`const double ASPECT_RATIO = 16.0 / 9.0;`
			`const int WIDTH = 384;`
			`const int HEIGHT = static_cast<int>(WIDTH / ASPECT_RATIO);`
add camera + multisampling 2020-06-06 22:11:09 +02:00			`const int SAMPLES_PER_PIXEL = 100;`
diffuse materials 2020-06-07 00:01:46 +02:00			`const int MAX_DEPTH = 50;`
add ray 2020-06-03 02:56:59 +02:00
diffuse materials 2020-06-07 00:01:46 +02:00			`colour ray_colour(const ray& r, const hittable& world, int depth)`
add ray 2020-06-03 02:56:59 +02:00			`{`
add hittable world 2020-06-06 19:28:30 +02:00			`hit_record rec;`
diffuse materials 2020-06-07 00:01:46 +02:00			`if (depth <= 0)`
			`{`
			`return colour(0,0,0);`
			`}`

add hittable world 2020-06-06 19:28:30 +02:00			`if (world.hit(r, 0, infinity, rec))`
Visualise surface normals 2020-06-06 04:54:05 +02:00			`{`
diffuse materials 2020-06-07 00:01:46 +02:00			`point3 target = rec.p + rec.normal + random_in_unit_sphere();`
			`return 0.5 * ray_colour(ray(rec.p, target - rec.p), world, depth-1);`
Visualise surface normals 2020-06-06 04:54:05 +02:00			`}`

use snake_case 2020-06-06 05:09:13 +02:00			`vec3 unit_direction = unit_vector(r.direction());`
add hittable world 2020-06-06 19:28:30 +02:00			`auto t = 0.5 * (unit_direction.y() + 1.0);`
linear interpolation for vectors 2020-06-04 01:47:33 +02:00
diffuse materials 2020-06-07 00:01:46 +02:00			`auto a = colour(0.5, 0.6, 0.7);`
			`auto b = colour(1.0, 1.0, 1.0);`
linear interpolation for vectors 2020-06-04 01:47:33 +02:00
			`return lerp(a, b, t);`
add ray 2020-06-03 02:56:59 +02:00			`}`
initial commit 2020-06-01 00:52:34 +02:00
			`int main()`
			`{`
add hittable world 2020-06-06 19:28:30 +02:00			`std::cout << "P3\n" << WIDTH << ' ' << HEIGHT << "\n255\n";`

use snake_case 2020-06-06 05:09:13 +02:00			`auto viewport_height = 2.0;`
			`auto viewport_width = ASPECT_RATIO * viewport_height;`
			`auto focal_length = 1.0;`
add ray 2020-06-03 02:56:59 +02:00
			`auto origin = point3(0, 0, 0);`
use snake_case 2020-06-06 05:09:13 +02:00			`auto horizontal = vec3(viewport_width, 0, 0);`
			`auto vertical = vec3(0, viewport_height, 0);`
			`auto lower_left_corner = origin - horizontal/2 - vertical/2 - vec3(0,0,focal_length);`
add ray 2020-06-03 02:56:59 +02:00
add hittable world 2020-06-06 19:28:30 +02:00			`hittable_list world;`
			`world.add(make_shared<sphere>(point3(0,0,-1), 0.5));`
			`world.add(make_shared<sphere>(point3(0,-100.5,-1), 100));`
initial commit 2020-06-01 00:52:34 +02:00
add camera + multisampling 2020-06-06 22:11:09 +02:00			`camera cam;`

			`for (int j = HEIGHT - 1; j >= 0; --j)`
initial commit 2020-06-01 00:52:34 +02:00			`{`
add camera + multisampling 2020-06-06 22:11:09 +02:00			`std::cerr << "\rScanlines remaining: " << j << ' ' << std::flush;`
			`for (int i = 0; i < WIDTH; ++i)`
initial commit 2020-06-01 00:52:34 +02:00			`{`
add camera + multisampling 2020-06-06 22:11:09 +02:00			`colour pixel_colour(0,0,0);`

			`for (int s = 0; s < SAMPLES_PER_PIXEL; ++s)`
			`{`
			`auto u = (i + random_double()) / (WIDTH-1);`
			`auto v = (j + random_double()) / (HEIGHT-1);`
			`ray r = cam.get_ray(u, v);`
diffuse materials 2020-06-07 00:01:46 +02:00			`pixel_colour += ray_colour(r, world, MAX_DEPTH);`
add camera + multisampling 2020-06-06 22:11:09 +02:00			`}`

			`write_colour(std::cout, pixel_colour, SAMPLES_PER_PIXEL);`
initial commit 2020-06-01 00:52:34 +02:00			`}`
			`}`

			`std::cerr << "\nDone." << std::endl;`
			`}`