1 use common::{Point, Dimension, Intersection, Angle, ToAngle, supercover_line};
2 use core::render::Renderer;
3 use sprites::SpriteManager;
9 pub use self::lvlgen::LevelGenerator;
11 ////////// LEVEL ///////////////////////////////////////////////////////////////
15 pub gravity: Point<f64>,
17 walls: Vec<WallRegion>,
18 wall_grid: Grid<Vec<Rc<WallEdge>>>,
22 pub fn new(gravity: Point<f64>, grid: Grid<bool>, mut walls: Vec<WallRegion>) -> Self {
23 let size = (2560, 1440); // TODO: get actual size from walls or something
24 let wall_grid = Level::build_wall_grid(&mut walls, &size.into());
25 dbg!(&wall_grid.scale);
34 /// Creates a grid of wall edges for fast lookup
35 fn build_wall_grid(walls: &mut Vec<WallRegion>, lvlsize: &Dimension<usize>) -> Grid<Vec<Rc<WallEdge>>> {
36 let size = dimen!(lvlsize.width / 20, lvlsize.height / 20); // TODO: make sure all walls fit within the grid bounds
37 let cs = point!(lvlsize.width / size.width, lvlsize.height / size.height);
38 //let cs = point!(scale.width as f64, scale.height as f64);
40 cells: vec!(vec!(vec!(); size.height); size.width),
42 scale: dimen!(cs.x as f64, cs.y as f64),
46 for edge in &wall.edges {
47 for c in grid.grid_coordinates_on_line(edge.p1, edge.p2) {
48 grid.cells[c.x][c.y].push(Rc::clone(edge));
56 pub fn render(&mut self, renderer: &mut Renderer, _sprites: &SpriteManager) {
58 renderer.canvas().set_draw_color((64, 64, 64));
59 let size = &self.grid.scale;
60 for x in 0..self.grid.size.width {
61 for y in 0..self.grid.size.height {
62 if self.grid.cells[x][y] {
63 renderer.canvas().fill_rect(sdl2::rect::Rect::new(
64 x as i32 * size.width as i32,
65 y as i32 * size.height as i32,
67 size.height as u32)).unwrap();
73 renderer.canvas().set_draw_color((0, 32, 0));
74 let size = &self.wall_grid.scale;
75 for x in 0..self.wall_grid.size.width {
76 for y in 0..self.wall_grid.size.height {
77 if !self.wall_grid.cells[x][y].is_empty() {
78 let num = self.wall_grid.cells[x][y].len();
79 renderer.canvas().set_draw_color((0, 32*num as u8, 0));
80 renderer.canvas().fill_rect(sdl2::rect::Rect::new(
81 x as i32 * size.width as i32,
82 y as i32 * size.height as i32,
84 size.height as u32)).unwrap();
90 for wall in &self.walls {
91 for e in &wall.edges {
92 let c = (e.p1 + e.p2) / 2.0;
93 let a = (e.p2 - e.p1).to_angle() + std::f64::consts::FRAC_PI_2.radians();
96 <(i32, i32)>::from(c.to_i32()),
97 <(i32, i32)>::from((c + Point::from(a) * 10.0).to_i32()),
101 <(i32, i32)>::from(e.p1.to_i32()),
102 <(i32, i32)>::from(e.p2.to_i32()),
108 pub fn intersect_walls(&self, p1: Point<f64>, p2: Point<f64>) -> IntersectResult {
109 for c in self.wall_grid.grid_coordinates_on_line(p1, p2) {
110 for w in &self.wall_grid.cells[c.x][c.y] {
111 if let Intersection::Point(p) = Intersection::lines(p1, p2, w.p1, w.p2) {
113 region: &self.walls[w.region],
116 return IntersectResult::Intersection(wall, p)
120 IntersectResult::None
124 pub enum IntersectResult<'a> {
125 Intersection(Wall<'a>, Point<f64>),
129 ////////// GRID ////////////////////////////////////////////////////////////////
131 #[derive(Debug, Default)]
133 pub size: Dimension<usize>,
134 pub scale: Dimension<f64>,
135 pub cells: Vec<Vec<T>>,
139 pub fn at<C>(&self, c: C) -> Option<&T>
140 where C: Into<(isize, isize)>
143 if c.0 >= 0 && c.0 < self.size.width as isize && c.1 >= 0 && c.1 < self.size.height as isize {
144 Some(&self.cells[c.0 as usize][c.1 as usize])
150 pub fn to_grid_coordinate<C>(&self, c: C) -> Option<Point<usize>>
151 where C: Into<(isize, isize)>
154 if c.0 >= 0 && c.0 < self.size.width as isize && c.1 >= 0 && c.1 < self.size.height as isize {
155 Some(point!(c.0 as usize, c.1 as usize))
161 /// Returns a list of grid coordinates that a line in world coordinates passes through.
162 pub fn grid_coordinates_on_line(&self, p1: Point<f64>, p2: Point<f64>) -> Vec<Point<usize>> {
163 supercover_line(p1 / self.scale, p2 / self.scale)
165 .map(|c| self.to_grid_coordinate(*c))
171 ////////// WALL REGION /////////////////////////////////////////////////////////
174 pub struct WallRegion {
175 edges: Vec<Rc<WallEdge>>,
179 pub fn new(points: Vec<Point<f64>>) -> Self {
180 let index: RegionIndex = 0; // use as param
181 let mut edges = Vec::with_capacity(points.len());
183 for i in 0..points.len() {
184 let edge = Rc::new(WallEdge {
188 p2: points[(i + 1) % points.len()],
196 // #[allow(dead_code)]
197 // fn next(&self, index: EdgeIndex) -> Rc<WallEdge> {
198 // let index = (index + 1) % self.edges.len();
199 // Rc::clone(&self.edges[index])
202 // #[allow(dead_code)]
203 // fn previous(&self, index: EdgeIndex) -> Rc<WallEdge> {
204 // let index = (index + self.edges.len() + 1) % self.edges.len();
205 // Rc::clone(&self.edges[index])
209 ////////// WALL EDGE ///////////////////////////////////////////////////////////
211 type RegionIndex = usize;
212 type EdgeIndex = usize;
214 #[derive(Debug, Default)]
222 ////////// WALL ////////////////////////////////////////////////////////////////
224 /// kommer det här att fungera ifall nåt objekt ska spara en referens till Wall?
225 /// kanske istället ska lägga Vec<WallRegion> i en Rc<Walls> och skicka med en klon av den, samt id:n till regionen och väggen?
226 pub struct Wall<'a> {
227 region: &'a WallRegion,
232 pub fn next(&self) -> Wall<'a> {
233 let next = (self.edge.id + 1) % self.region.edges.len();
234 let edge = &self.region.edges[next];
241 pub fn previous(&self) -> Wall<'a> {
242 let prev = (self.edge.id + self.region.edges.len() - 1) % self.region.edges.len();
243 let edge = &self.region.edges[prev];
250 pub fn normal(&self) -> Angle {
251 (self.edge.p2 - self.edge.p1).to_angle() + std::f64::consts::FRAC_PI_2.radians()