#include "Software_Caster.h" Software_Caster::Software_Caster() { } Software_Caster::~Software_Caster() { } int Software_Caster::init() { return 1; } void Software_Caster::create_viewport(int width, int height, float v_fov, float h_fov) { // CL needs the screen resolution viewport_resolution = sf::Vector2i(width, height); // And an array of vectors describing the way the "lens" of our // camera works // This could be modified to make some odd looking camera lenses double y_increment_radians = DegreesToRadians(v_fov / viewport_resolution.y); double x_increment_radians = DegreesToRadians(h_fov / viewport_resolution.x); viewport_matrix = new sf::Vector4f[width * height * 4]; for (int y = -viewport_resolution.y / 2; y < viewport_resolution.y / 2; y++) { for (int x = -viewport_resolution.x / 2; x < viewport_resolution.x / 2; x++) { // The base ray direction to slew from sf::Vector3f ray(1, 0, 0); // Y axis, pitch ray = sf::Vector3f( static_cast(ray.z * sin(y_increment_radians * y) + ray.x * cos(y_increment_radians * y)), static_cast(ray.y), static_cast(ray.z * cos(y_increment_radians * y) - ray.x * sin(y_increment_radians * y)) ); // Z axis, yaw ray = sf::Vector3f( static_cast(ray.x * cos(x_increment_radians * x) - ray.y * sin(x_increment_radians * x)), static_cast(ray.x * sin(x_increment_radians * x) + ray.y * cos(x_increment_radians * x)), static_cast(ray.z) ); int index = (x + viewport_resolution.x / 2) + viewport_resolution.x * (y + viewport_resolution.y / 2); ray = Normalize(ray); viewport_matrix[index] = sf::Vector4f( ray.x, ray.y, ray.z, 0 ); } } // Create the image that opencl's rays write to viewport_image = new sf::Uint8[width * height * 4]; for (int i = 0; i < width * height * 4; i += 4) { viewport_image[i] = 255; // R viewport_image[i + 1] = 255; // G viewport_image[i + 2] = 255; // B viewport_image[i + 3] = 255; // A } // Interop lets us keep a reference to it as a texture viewport_texture.create(width, height); viewport_texture.update(viewport_image); viewport_sprite.setTexture(viewport_texture); } void Software_Caster::assign_lights(std::vector lights) { this->lights = std::vector(lights); int light_count = static_cast(lights.size()); } void Software_Caster::assign_map(Old_Map * map) { this->map = map; } void Software_Caster::assign_camera(Camera * camera) { this->camera = camera; } void Software_Caster::validate() { // Check to make sure everything has been entered; if (camera == nullptr || map == nullptr || viewport_image == nullptr || viewport_matrix == nullptr) { std::cout << "Raycaster.validate() failed, camera, map, or viewport not initialized"; } } void Software_Caster::compute() { cast_viewport(); } void Software_Caster::draw(sf::RenderWindow * window) { viewport_texture.update(viewport_image); window->draw(viewport_sprite); } void Software_Caster::cast_viewport() { std::vector threads; for (int i = 0; i < 13; i++) { int s = viewport_resolution.x * ((viewport_resolution.y / 13) * i); int e = viewport_resolution.x * ((viewport_resolution.y / 13) * (i + 1)); threads.push_back(new std::thread(&Software_Caster::cast_thread, this, s, e)); } for (auto i : threads) { i->join(); delete i; } } void Software_Caster::cast_thread(int start_id, int end_id) { for (int i = start_id; i < end_id; i++) { cast_ray(i); } } void Software_Caster::cast_ray(int id) { sf::Vector2i pixel = { id % viewport_resolution.x, id / viewport_resolution.x }; // 4f 3f ?? sf::Vector4f ray_dir = viewport_matrix[pixel.x + viewport_resolution.x * pixel.y]; ray_dir = sf::Vector4f( ray_dir.z * sin(camera->get_direction().x) + ray_dir.x * cos(camera->get_direction().x), ray_dir.y, ray_dir.z * cos(camera->get_direction().x) - ray_dir.x * sin(camera->get_direction().x), 0 ); ray_dir = sf::Vector4f( ray_dir.x * cos(camera->get_direction().y) - ray_dir.y * sin(camera->get_direction().y), ray_dir.x * sin(camera->get_direction().y) + ray_dir.y * cos(camera->get_direction().y), ray_dir.z, 0 ); // Setup the voxel step based on what direction the ray is pointing sf::Vector3i voxel_step = sf::Vector3i( static_cast(1 * (abs(ray_dir.x) / ray_dir.x)), static_cast(1 * (abs(ray_dir.y) / ray_dir.y)), static_cast(1 * (abs(ray_dir.z) / ray_dir.z)) ); // Setup the voxel coords from the camera origin sf::Vector3i voxel = sf::Vector3i( static_cast(camera->get_position().x), static_cast(camera->get_position().y), static_cast(camera->get_position().z) ); // Delta T is the units a ray must travel along an axis in order to // traverse an integer split sf::Vector3f delta_t = sf::Vector3f( fabs(1.0f / ray_dir.x), fabs(1.0f / ray_dir.y), fabs(1.0f / ray_dir.z) ); // offset is how far we are into a voxel, enables sub voxel movement sf::Vector3f offset = sf::Vector3f( (camera->get_position().x - floor(camera->get_position().x)) * voxel_step.x, (camera->get_position().y - floor(camera->get_position().y)) * voxel_step.y, (camera->get_position().z - floor(camera->get_position().z)) * voxel_step.z ); // Intersection T is the collection of the next intersection points // for all 3 axis XYZ. sf::Vector3f intersection_t = sf::Vector3f( delta_t.x * offset.x, delta_t.y * offset.y, delta_t.z * offset.z ); // for negative values, wrap around the delta_t, rather not do this // component wise, but it doesn't appear to want to work if (intersection_t.x < 0) { intersection_t.x += delta_t.x; } if (intersection_t.y < 0) { intersection_t.y += delta_t.y; } if (intersection_t.z < 0) { intersection_t.z += delta_t.z; } // use a ghetto ass rng to give rays a "fog" appearance sf::Vector2i randoms = { 3, 14 }; int seed = randoms.x + id; int t = seed ^ (seed << 11); int result = randoms.y ^ (randoms.y >> 19) ^ (t ^ (t >> 8)); int max_dist = 800 + result % 50; int dist = 0; sf::Vector3i mask = { 0, 0, 0 }; // Andrew Woo's raycasting algo do { if ((intersection_t.x) < (intersection_t.y)) { if ((intersection_t.x) < (intersection_t.z)) { mask.x = 1; voxel.x += voxel_step.x; intersection_t.x = intersection_t.x + delta_t.x; } else { mask.z = 1; voxel.z += voxel_step.z; intersection_t.z = intersection_t.z + delta_t.z; } } else { if ((intersection_t.y) < (intersection_t.z)) { mask.y = 1; voxel.y += voxel_step.y; intersection_t.y = intersection_t.y + delta_t.y; } else { mask.z = 1; voxel.z += voxel_step.z; intersection_t.z = intersection_t.z + delta_t.z; } } // If the ray went out of bounds sf::Vector3i overshoot = sf::Vector3i( voxel.x <= map->getDimensions().x, voxel.y <= map->getDimensions().y, voxel.z <= map->getDimensions().z ); sf::Vector3i undershoot = sf::Vector3i( voxel.x > 0, voxel.y > 0, voxel.z > 0 ); if (overshoot.x == 0 || overshoot.y == 0 || overshoot.z == 0 || undershoot.x == 0 || undershoot.y == 0) { blit_pixel(sf::Color::Yellow, sf::Vector2i{ pixel.x,pixel.y }, mask); return; } if (undershoot.z == 0) { blit_pixel(sf::Color::Yellow, sf::Vector2i{ pixel.x,pixel.y }, mask); return; } // If we hit a voxel //int index = voxel.x * (*map_dim).y * (*map_dim).z + voxel.z * (*map_dim).z + voxel.y; // Why the off by one on voxel.y? int index = voxel.x + map->getDimensions().x * (voxel.y + map->getDimensions().z * (voxel.z - 1)); int voxel_data = map->get_voxel_data()[index]; if (voxel_data != 0) { switch (voxel_data) { case 1: blit_pixel(sf::Color::Green, sf::Vector2i{ pixel.x,pixel.y }, mask); return; case 2: blit_pixel(sf::Color::Green, sf::Vector2i{ pixel.x,pixel.y }, mask); return; case 3: blit_pixel(sf::Color::Green, sf::Vector2i{ pixel.x,pixel.y }, mask); return; case 4: blit_pixel(sf::Color::Green, sf::Vector2i{ pixel.x,pixel.y }, mask); return; case 5: blit_pixel(sf::Color(30, 10, 200, 100), sf::Vector2i{ pixel.x,pixel.y }, mask); return; case 6: blit_pixel(sf::Color::Green, sf::Vector2i{ pixel.x,pixel.y }, mask); return; default: //write_imagef(image, pixel, (float4)(.30, .2550, .2550, 255.00)); return; } } dist++; } while (dist < max_dist); blit_pixel(sf::Color::Red, sf::Vector2i{ pixel.x,pixel.y }, mask); return; } void Software_Caster::blit_pixel(sf::Color color, sf::Vector2i position, sf::Vector3i mask) { sf::Color t = global_light(color, mask); viewport_image[(position.x + viewport_resolution.x * position.y) * 4 + 0] = t.r; viewport_image[(position.x + viewport_resolution.x * position.y) * 4 + 1] = t.g; viewport_image[(position.x + viewport_resolution.x * position.y) * 4 + 2] = t.b; viewport_image[(position.x + viewport_resolution.x * position.y) * 4 + 3] = t.a; } sf::Color Software_Caster::global_light(sf::Color in, sf::Vector3i mask) { sf::Vector3f mask_f(mask); in.a = in.a + acos( DotProduct( Normalize(lights.at(0).direction_cartesian), Normalize(mask_f) ) )/ 2; return in; }