use common::Point2D;
+use ::{point, time_scope};
use core::render::Renderer;
+use noise::{NoiseFn, OpenSimplex, Seedable};
use rand::Rng;
use sprites::SpriteManager;
#[derive(Default)]
pub struct Level {
pub gravity: Point2D<f64>,
- pub ground: f64, // just to have something
pub grid: Grid,
iterations: u8,
+ walls: Vec<Vec<Point2D<isize>>>,
}
impl Level {
- pub fn new(gravity: Point2D<f64>, ground: f64) -> Self {
- Level { gravity, ground, grid: Grid::generate(10), iterations: 10 }
+ pub fn new(gravity: Point2D<f64>) -> Self {
+ let mut lvl = Level { gravity, grid: Grid::generate(10), iterations: 10, walls: vec!() };
+ lvl.filter_regions();
+ lvl
}
- pub fn regenerate(&mut self) {
+ fn generate(&mut self) {
self.grid = Grid::generate(self.iterations);
}
pub fn increase_iteration(&mut self) {
self.iterations += 1;
- self.regenerate();
+ self.generate();
println!("iterate {} time(s)", self.iterations);
}
pub fn decrease_iteration(&mut self) {
self.iterations -= 1;
- self.regenerate();
+ self.generate();
println!("iterate {} time(s)", self.iterations);
}
pub fn filter_regions(&mut self) {
self.grid.filter_regions();
+ let mut walls = vec!();
+ for mut r in self.grid.find_regions() {
+ if r.value {
+ let mut outline = r.outline(self.grid.cell_size);
+ for i in 2..(outline.len() - 2) {
+// outline[i] = (outline[i - 1] + outline[i] + outline[i + 1]) / 3;
+ outline[i] = (outline[i - 2] + outline[i - 1] + outline[i] + outline[i + 1] + outline[i + 2]) / 5;
+ }
+ walls.push(outline);
+ }
+ }
+ self.walls = walls;
}
pub fn render(&mut self, renderer: &mut Renderer, _sprites: &SpriteManager) {
- let w = renderer.viewport().0 as i32;
-
renderer.canvas().set_draw_color((64, 64, 64));
let size = self.grid.cell_size;
for x in 0..self.grid.width {
}
}
- for i in 1..11 {
- let y = (i * i - 1) as i32 + self.ground as i32;
- renderer.canvas().set_draw_color((255 - i * 20, 255 - i * 20, 0));
- renderer.canvas().draw_line((0, y), (w, y)).unwrap();
+ let off = (size / 2) as i32;
+ for wall in &self.walls {
+ for w in wall.windows(2) {
+ renderer.draw_line((w[0].x as i32 + off, w[0].y as i32 + off), (w[1].x as i32 + off, w[1].y as i32 + off), (255, 255, 0));
+ }
+ let last = wall.len() - 1;
+ renderer.draw_line((wall[0].x as i32 + off, wall[0].y as i32 + off), (wall[last].x as i32 + off, wall[last].y as i32 + off), (255, 255, 0));
}
}
}
////////// GRID ////////////////////////////////////////////////////////////////
+
#[derive(Default)]
pub struct Grid {
pub width: usize,
impl Grid {
fn generate(iterations: u8) -> Grid {
+ time_scope!("grid generation");
+
let cell_size = 20;
let (width, height) = (2560 / cell_size, 1440 / cell_size);
#[allow(dead_code)]
fn simplex_noise(&mut self) {
- use noise::{NoiseFn, OpenSimplex, Seedable};
let noise = OpenSimplex::new().set_seed(std::time::SystemTime::now().duration_since(std::time::UNIX_EPOCH).unwrap().as_secs() as u32);
self.set_each(|x, y| noise.get([x as f64 / 12.0, y as f64 / 12.0]) > 0.055, 1);
}
#[allow(dead_code)]
fn random_noise(&mut self) {
let mut rng = rand::thread_rng();
- self.set_each(|_x, _y| rng.gen_range(0, 100) > 55, 1);
+ let noise = OpenSimplex::new().set_seed(std::time::SystemTime::now().duration_since(std::time::UNIX_EPOCH).unwrap().as_secs() as u32);
+ self.set_each(|_x, _y| rng.gen_range(0, 100) > (45 + (150.0 * noise.get([_x as f64 / 40.0, _y as f64 / 10.0])) as usize), 1); // more horizontal platforms
+ // let w = self.width as f64;
+ // self.set_each(|_x, _y| rng.gen_range(0, 100) > (45 + ((15 * _x) as f64 / w) as usize), 1); // opens up to the right
}
#[allow(dead_code)]
}
fn find_regions(&self) -> Vec<Region> {
+ time_scope!("finding all regions");
let mut regions = vec!();
let mut marked = vec!(vec!(false; self.height); self.width);
for x in 0..self.width {
value: bool,
cells: Vec<(usize, usize)>,
}
+
+impl Region {
+ fn enclosing_rect(&self) -> (usize, usize, usize, usize) {
+ let mut min = (usize::MAX, usize::MAX);
+ let mut max = (0, 0);
+ for c in &self.cells {
+ if c.0 < min.0 { min.0 = c.0; }
+ else if c.0 > max.0 { max.0 = c.0; }
+ if c.1 < min.1 { min.1 = c.1; }
+ else if c.1 > max.1 { max.1 = c.1; }
+ }
+ (min.0, min.1, 1 + max.0 - min.0, 1 + max.1 - min.1)
+ }
+
+ pub fn outline(&mut self, scale: usize) -> Vec<Point2D<isize>> {
+ let rect = self.enclosing_rect();
+ let (ox, oy, w, h) = rect;
+ let grid = self.grid(&rect);
+ let mut marked = vec!(vec!(false; h); w);
+ let mut outline = vec!();
+
+ let (mut p, mut dir) = self.find_first_point_of_outline(&rect, &grid);
+// println!("starting at {:?} with dir {:?}", p, dir);
+ marked[p.x as usize][p.y as usize] = true;
+ loop {
+ outline.push((p + (ox as isize, oy as isize)) * scale as isize);
+ let result = self.find_next_point_of_outline(&grid, p, dir);
+ p = result.0;
+ dir = result.1;
+// println!("next at {:?} with dir {:?}", p, dir);
+ if marked[p.x as usize][p.y as usize] {
+ // we're back at the beginning
+ break;
+ }
+ marked[p.x as usize][p.y as usize] = true;
+ }
+
+ outline
+ }
+
+ fn grid(&self, rect: &(usize, usize, usize, usize)) -> Vec<Vec<bool>> {
+ let (x, y, w, h) = rect;
+ let mut grid = vec!(vec!(false; *h); *w);
+ for c in &self.cells {
+ grid[c.0 - x][c.1 - y] = true;
+ }
+ grid
+ }
+
+ fn find_first_point_of_outline(&self, rect: &(usize, usize, usize, usize), grid: &Vec<Vec<bool>>) -> (Point2D<isize>, Point2D<isize>) {
+ let (ox, oy, w, h) = rect;
+ let is_outer_wall = (ox, oy) == (&0, &0); // we know this is always the outer wall of the level
+ for x in 0..*w {
+ for y in 0..*h {
+ if is_outer_wall && !grid[x][y] {
+ return (point!(x as isize, y as isize - 1), point!(0, 1)) // one step back because we're not on a wall tile
+ }
+ else if !is_outer_wall && grid[x][y] {
+ return (point!(x as isize, y as isize), point!(1, 0))
+ }
+ }
+ }
+ panic!("no wall found!");
+ }
+
+ fn find_next_point_of_outline(&self, grid: &Vec<Vec<bool>>, p: Point2D<isize>, dir: Point2D<isize>) -> (Point2D<isize>, Point2D<isize>) {
+ let left = match dir.into() {
+ (-1, 0) => (0, 1),
+ (0, 1) => (1, 0),
+ (1, 0) => (0, -1),
+ (0, -1) => (-1, 0),
+ _ => (0, 0),
+ };
+ let right = match dir.into() {
+ (0, 1) => (-1, 0),
+ (1, 0) => (0, 1),
+ (0, -1) => (1, 0),
+ (-1, 0) => (0, -1),
+ _ => (0, 0),
+ };
+ if self.check(p + dir, grid) {
+// println!("{:?} is true", p + dir);
+ if self.check(p + dir + left, grid) {
+// println!("going left to {:?}", p + dir + left);
+ return (p + dir + left, left.into())
+ } else {
+ return (p + dir, dir)
+ }
+ } else {
+// println!("{:?} is false", p + dir);
+ if self.check(p + dir + right, grid) {
+// println!("going right to {:?}", p + dir + right);
+ return (p + dir + right, dir)
+ } else {
+// println!("going right from p to {:?}", p + right);
+ return (p + right, right.into())
+ }
+ }
+ }
+
+ fn check(&self, p: Point2D<isize>, grid: &Vec<Vec<bool>>) -> bool {
+ if p.x < 0 || p.x >= grid.len() as isize || p.y < 0 || p.y >= grid[0].len() as isize {
+ false
+ } else {
+ grid[p.x as usize][p.y as usize]
+ }
+ }
+}