/* * Copyright (c) 2022, Jelle Raaijmakers * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include #include constexpr size_t grid_resolution = 15; constexpr int mouse_max_distance_move = 10; constexpr int reset_every_ticks = 900; constexpr double rotation_range = 35.; constexpr u8 tube_maximum_count = 12; constexpr u8 tube_minimum_count = 3; constexpr double tube_movement_per_tick = .25; constexpr double tube_relative_thickness = .6; constexpr int tube_travel_max_stretch = 6; static double random_double() { return get_random() / static_cast(NumericLimits::max()); } static int random_int(int min, int max) { return min + round_to(random_double() * (max - min)); } static IntVector4 tube_rotation_for_direction(Direction direction) { switch (direction) { case Direction::XPositive: return { 0, 1, 0, -90 }; case Direction::XNegative: return { 0, 1, 0, 90 }; case Direction::YPositive: return { 1, 0, 0, 90 }; case Direction::YNegative: return { 1, 0, 0, -90 }; case Direction::ZPositive: return { 0, 1, 0, 180 }; case Direction::ZNegative: return { 0, 0, 0, 0 }; default: VERIFY_NOT_REACHED(); } } static IntVector3 vector_for_direction(Direction direction) { switch (direction) { case Direction::XPositive: return { 1, 0, 0 }; case Direction::XNegative: return { -1, 0, 0 }; case Direction::YPositive: return { 0, 1, 0 }; case Direction::YNegative: return { 0, -1, 0 }; case Direction::ZPositive: return { 0, 0, 1 }; case Direction::ZNegative: return { 0, 0, -1 }; default: VERIFY_NOT_REACHED(); } } Tubes::Tubes(int interval) : m_grid(MUST(FixedArray::try_create(grid_resolution * grid_resolution * grid_resolution))) { start_timer(interval); } void Tubes::choose_new_direction_for_tube(Tube& tube) { // Find all possible directions Vector possible_directions; for (int i = 1; i <= 6; ++i) { auto direction = static_cast(i); auto direction_vector = vector_for_direction(direction); auto check_position = tube.position + direction_vector; if (is_valid_grid_position(check_position) && get_grid(check_position) == 0) possible_directions.append(direction); } // If tube is stuck, kill it :^( if (possible_directions.is_empty()) { tube.direction = Direction::None; tube.active = false; return; } // Remove our old direction if we have other options available Direction const old_direction = tube.direction; if (possible_directions.size() >= 2 && possible_directions.contains_slow(old_direction)) possible_directions.remove_all_matching([&old_direction](Direction const& item) { return item == old_direction; }); // Select a random new direction tube.direction = possible_directions[random_int(0, static_cast(possible_directions.size()) - 1)]; // Determine how far we can go in this direction auto direction_vector = vector_for_direction(tube.direction); int max_stretch = random_int(1, tube_travel_max_stretch); IntVector3 new_target = tube.position; while (max_stretch-- > 0) { new_target += direction_vector; if (!is_valid_grid_position(new_target) || get_grid(new_target) != 0) break; set_grid(new_target, 1); tube.target_position = new_target; } tube.progress_to_target = 0.; } ErrorOr Tubes::create_buffer(Gfx::IntSize size) { m_bitmap = TRY(Gfx::Bitmap::try_create(Gfx::BitmapFormat::BGRx8888, size)); m_gl_context = TRY(GL::create_context(*m_bitmap)); return {}; } u8 Tubes::get_grid(IntVector3 position) { return m_grid[position.z() * grid_resolution * grid_resolution + position.y() * grid_resolution + position.x()]; } bool Tubes::is_valid_grid_position(Gfx::IntVector3 position) { return position.x() >= 0 && position.x() < static_cast(grid_resolution) && position.y() >= 0 && position.y() < static_cast(grid_resolution) && position.z() >= 0 && position.z() < static_cast(grid_resolution); } void Tubes::set_grid(IntVector3 position, u8 value) { m_grid[position.z() * grid_resolution * grid_resolution + position.y() * grid_resolution + position.x()] = value; } void Tubes::mousemove_event(GUI::MouseEvent& event) { if (m_mouse_origin.is_null()) { m_mouse_origin = event.position(); } else if (event.position().distance_from(m_mouse_origin) > mouse_max_distance_move) { GUI::Application::the()->quit(); } } void Tubes::mousedown_event(GUI::MouseEvent&) { GUI::Application::the()->quit(); } void Tubes::keydown_event(GUI::KeyEvent&) { GUI::Application::the()->quit(); } void Tubes::paint_event(GUI::PaintEvent& event) { GUI::Painter painter(*this); painter.add_clip_rect(event.rect()); painter.blit(rect().location(), *m_bitmap, m_bitmap->rect()); } void Tubes::reset_tubes() { glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT); // Random rotation glMatrixMode(GL_PROJECTION); glPopMatrix(); glPushMatrix(); glRotated((random_double() - .5) * 2 * rotation_range, 0., 1., 0.); glMatrixMode(GL_MODELVIEW); // Clear grid m_grid.fill_with(0); // Create new set of tubes auto free_grid_position = [&]() { for (;;) { IntVector3 position = { random_int(0, grid_resolution - 1), random_int(0, grid_resolution - 1), random_int(0, grid_resolution - 1), }; if (get_grid(position) != 0) continue; return position; } }; m_tubes.clear_with_capacity(); int tube_count = random_int(tube_minimum_count, tube_maximum_count); while (tube_count-- > 0) { Tube new_tube = { .color = { random_double(), random_double(), random_double(), }, .position = free_grid_position(), }; choose_new_direction_for_tube(new_tube); m_tubes.append(new_tube); set_grid(new_tube.position, 1); } } void Tubes::setup_view() { glClearColor(0.f, 0.f, 0.f, 1.f); glMatrixMode(GL_PROJECTION); double const zoom = .25; auto const half_aspect_ratio = static_cast(m_bitmap->width()) / m_bitmap->height() * zoom; glFrustum(-half_aspect_ratio, half_aspect_ratio, -zoom, zoom, .5, 10.); glTranslated(0., 0., -2.); glPushMatrix(); glMatrixMode(GL_MODELVIEW); // Set up lighting glEnable(GL_LIGHTING); glEnable(GL_LIGHT0); GLfloat light_ambient[] { .0f, .0f, .0f, 1.f }; glLightfv(GL_LIGHT0, GL_AMBIENT, light_ambient); GLfloat light_diffuse[] { 1.f, 1.f, 1.f, 1.f }; glLightfv(GL_LIGHT0, GL_DIFFUSE, light_diffuse); GLfloat light_specular[] { 1.f, 1.f, 1.f, 1.f }; glLightfv(GL_LIGHT0, GL_SPECULAR, light_specular); GLfloat light_position[] { .5f, 1.f, .5f, 0.f }; glLightfv(GL_LIGHT0, GL_POSITION, light_position); GLfloat mat_specular[] { 1.f, 1.f, 1.f, 1.f }; glMaterialfv(GL_FRONT, GL_SPECULAR, mat_specular); glMaterialf(GL_FRONT, GL_SHININESS, 8.f); // Adapt the vertex color as ambient and diffuse colors glEnable(GL_COLOR_MATERIAL); glColorMaterial(GL_FRONT, GL_AMBIENT_AND_DIFFUSE); glEnable(GL_DEPTH_TEST); glDepthFunc(GL_LEQUAL); glEnable(GL_NORMALIZE); glShadeModel(GL_SMOOTH); } void Tubes::timer_event(Core::TimerEvent&) { update_tubes(); m_gl_context->present(); repaint(); } void Tubes::update_tubes() { if (++m_ticks % reset_every_ticks == 0) reset_tubes(); double const primitive_size = 2.; // our tubes and spheres are 1 in diameter, so object size is 2 double const grid_width = 2.; double const grid_scale = 1. / grid_resolution; double const primitive_scale = 1. / primitive_size; double const tube_length_scale = tube_movement_per_tick * primitive_size; double const tube_thickness_scale = tube_relative_thickness * primitive_scale; for (auto& tube : m_tubes) { if (!tube.active) continue; glColor3d(tube.color.x(), tube.color.y(), tube.color.z()); glPushMatrix(); auto pos = tube.position; glTranslated( pos.x() * grid_scale * grid_width - (grid_width / 2.), pos.y() * grid_scale * grid_width - (grid_width / 2.), pos.z() * grid_scale * grid_width - (grid_width / 2.)); glScaled(grid_scale, grid_scale, grid_scale); // Draw sphere if we're at the start or a corner if (tube.progress_to_target == 0.) { glPushMatrix(); glScaled(tube_thickness_scale, tube_thickness_scale, tube_thickness_scale); draw_sphere(); glPopMatrix(); } // Draw tube at the current position glPushMatrix(); auto direction_vector = vector_for_direction(tube.direction); auto distance_to_target = (tube.target_position - tube.position).length(); auto movement_magnitude = tube.progress_to_target * (distance_to_target - tube_movement_per_tick) / distance_to_target * grid_width; glTranslated( direction_vector.x() * movement_magnitude, direction_vector.y() * movement_magnitude, direction_vector.z() * movement_magnitude); auto tube_rotation = tube_rotation_for_direction(tube.direction); glRotated(tube_rotation.w(), tube_rotation.x(), tube_rotation.y(), tube_rotation.z()); glScaled(tube_thickness_scale, tube_thickness_scale, primitive_scale * tube_length_scale); draw_tube(); glPopMatrix(); // Move towards target if (tube.progress_to_target >= distance_to_target) { tube.position = tube.target_position; choose_new_direction_for_tube(tube); } else { tube.progress_to_target = min(tube.progress_to_target + tube_movement_per_tick, distance_to_target); } glPopMatrix(); } }