[kaka/rust-sdl-test.git] / src / core / level.rs

use common::Point2D;
use core::render::Renderer;
use noise::{NoiseFn, OpenSimplex, Seedable};
use rand::Rng;
use sprites::SpriteManager;

////////// LEVEL ///////////////////////////////////////////////////////////////

#[derive(Default)]
pub struct Level {
    pub gravity: Point2D<f64>,
    pub grid: Grid,
    iterations: u8,
}

impl Level {
    pub fn new(gravity: Point2D<f64>) -> Self {
	Level { gravity, grid: Grid::generate(10), iterations: 10 }
    }

    pub fn regenerate(&mut self) {
	self.grid = Grid::generate(self.iterations);
    }

    pub fn increase_iteration(&mut self) {
	self.iterations += 1;
	self.regenerate();
	println!("iterate {} time(s)", self.iterations);
    }

    pub fn decrease_iteration(&mut self) {
	self.iterations -= 1;
	self.regenerate();
	println!("iterate {} time(s)", self.iterations);
    }

    pub fn filter_regions(&mut self) {
	self.grid.filter_regions();
    }

    pub fn render(&mut self, renderer: &mut Renderer, _sprites: &SpriteManager) {
	renderer.canvas().set_draw_color((64, 64, 64));
	let size = self.grid.cell_size;
	for x in 0..self.grid.width {
	    for y in 0..self.grid.height {
		if self.grid.cells[x][y] {
		    renderer.canvas().fill_rect(sdl2::rect::Rect::new(x as i32 * size as i32, y as i32 * size as i32, size as u32, size as u32)).unwrap();
		}
	    }
	}
    }
}

////////// GRID ////////////////////////////////////////////////////////////////

#[derive(Default)]
pub struct Grid {
    pub width: usize,
    pub height: usize,
    pub cell_size: usize,
    pub cells: Vec<Vec<bool>>,
}

impl Grid {
    fn generate(iterations: u8) -> Grid {
	let cell_size = 20;
	let (width, height) = (2560 / cell_size, 1440 / cell_size);

	let mut grid = Grid {
	    cell_size,
	    width,
	    height,
	    cells: vec!(vec!(true; height); width),
	};

	// start with some noise
//	grid.simplex_noise();
	grid.random_noise();

	// smooth with cellular automata
	grid.smooth(iterations);
//	grid.smooth_until_equilibrium();

	// increase resolution
	for _i in 0..1 {
	    grid = grid.subdivide();
	    grid.smooth(iterations);
	}

	grid
    }

    #[allow(dead_code)]
    fn simplex_noise(&mut self) {
	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();
	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 smooth(&mut self, iterations: u8) {
	let distance = 1;
	for _i in 0..iterations {
	    let mut next = vec!(vec!(true; self.height); self.width);
	    for x in distance..(self.width - distance) {
	    	for y in distance..(self.height - distance) {
		    match Grid::neighbours(&self.cells, x, y, distance) {
			n if n < 4 => next[x][y] = false,
			n if n > 4 => next[x][y] = true,
			_ => next[x][y] = self.cells[x][y]
		    }
		}
	    }
	    if self.cells == next {
		break; // exit early
	    } else {
		self.cells = next;
	    }
	}
    }

    #[allow(dead_code)]
    fn smooth_until_equilibrium(&mut self) {
	let distance = 1;
	let mut count = 0;
	loop {
	    count += 1;
	    let mut next = vec!(vec!(true; self.height); self.width);
	    for x in distance..(self.width - distance) {
		for y in distance..(self.height - distance) {
		    match Grid::neighbours(&self.cells, x, y, distance) {
			n if n < 4 => next[x][y] = false,
			n if n > 4 => next[x][y] = true,
			_ => next[x][y] = self.cells[x][y]
		    };
		}
	    }
	    if self.cells == next {
		break;
	    } else {
		self.cells = next;
	    }
	}
	println!("{} iterations needed", count);
    }

    fn neighbours(grid: &Vec<Vec<bool>>, px: usize, py: usize, distance: usize) -> u8 {
	let mut count = 0;
	for x in (px - distance)..=(px + distance) {
	    for y in (py - distance)..=(py + distance) {
		if !(x == px && y == py) && grid[x][y] {
		    count += 1;
		}
	    }
	}
	count
    }

    fn set_each<F: FnMut(usize, usize) -> bool>(&mut self, mut func: F, walls: usize) {
    	for x in walls..(self.width - walls) {
    	    for y in walls..(self.height - walls) {
    		self.cells[x][y] = func(x, y);
    	    }
    	}
    }

    fn subdivide(&mut self) -> Grid {
	let (width, height) = (self.width * 2, self.height * 2);
	let mut cells = vec!(vec!(true; height); width);
	for x in 1..(width - 1) {
	    for y in 1..(height - 1) {
		cells[x][y] = self.cells[x / 2][y / 2];
	    }
	}
	Grid {
	    cell_size: self.cell_size / 2,
	    width,
	    height,
	    cells
	}
    }

    fn find_regions(&self) -> Vec<Region> {
	let mut regions = vec!();
	let mut marked = vec!(vec!(false; self.height); self.width);
	for x in 0..self.width {
	    for y in 0..self.height {
		if !marked[x][y] {
		    regions.push(self.get_region_at_point(x, y, &mut marked));
		}
	    }
	}
	regions
    }

    fn get_region_at_point(&self, x: usize, y: usize, marked: &mut Vec<Vec<bool>>) -> Region {
	let value = self.cells[x][y];
	let mut cells = vec!();
	let mut queue = vec!((x, y));
	marked[x][y] = true;

	while let Some(p) = queue.pop() {
	    cells.push(p);
	    for i in &[(-1, 0), (1, 0), (0, -1), (0, 1)] {
		let ip = (p.0 as isize + i.0, p.1 as isize + i.1);
		if ip.0 >= 0 && ip.0 < self.width as isize && ip.1 >= 0 && ip.1 < self.height as isize {
		    let up = (ip.0 as usize, ip.1 as usize);
		    if self.cells[up.0][up.1] == value && !marked[up.0][up.1] {
			marked[up.0][up.1] = true;
			queue.push(up);
		    }
		}
	    }
	}

	Region { value, cells }
    }

    fn delete_region(&mut self, region: &Region) {
	for c in &region.cells {
	    self.cells[c.0][c.1] = !region.value;
	}
    }

    pub fn filter_regions(&mut self) {
	let min_wall_size = 0.0015;
	println!("grid size: ({}, {}) = {} cells", self.width, self.height, self.width * self.height);
	println!("min wall size: {}", (self.width * self.height) as f64 * min_wall_size);

	// delete all smaller wall regions
	for r in self.find_regions().iter().filter(|r| r.value) {
	    let percent = r.cells.len() as f64 / (self.width * self.height) as f64;
	    if percent < min_wall_size {
		println!("delete wall region of size {}", r.cells.len());
		self.delete_region(r);
	    }
	}

	// delete all rooms but the largest
	let regions = self.find_regions(); // check again, because if a removed room contains a removed wall, the removed wall will become a room
	let mut rooms: Vec<&Region> = regions.iter().filter(|r| !r.value).collect();
	rooms.sort_by_key(|r| r.cells.len());
	rooms.reverse();
	while rooms.len() > 1 {
	    self.delete_region(rooms.pop().unwrap());
	}
    }
}

////////// REGION //////////////////////////////////////////////////////////////

struct Region {
    value: bool,
    cells: Vec<(usize, usize)>,
}
Commit	Line	Data
a6b57e45 TW	1	use common::Point2D;
a6b57e45 TW	2	use core::render::Renderer;
3fd8761b	3	use noise::{NoiseFn, OpenSimplex, Seedable};
a6b57e45 TW	4	use rand::Rng;
	5	use sprites::SpriteManager;
	6
	7	////////// LEVEL ///////////////////////////////////////////////////////////////
	8
	9	#[derive(Default)]
	10	pub struct Level {
	11	pub gravity: Point2D<f64>,
a6b57e45 TW	12	pub grid: Grid,
	13	iterations: u8,
	14	}
	15
	16	impl Level {
3fd8761b TW	17	pub fn new(gravity: Point2D<f64>) -> Self {
3fd8761b TW	18	Level { gravity, grid: Grid::generate(10), iterations: 10 }
a6b57e45 TW	19	}
	20
	21	pub fn regenerate(&mut self) {
	22	self.grid = Grid::generate(self.iterations);
	23	}
	24
	25	pub fn increase_iteration(&mut self) {
	26	self.iterations += 1;
	27	self.regenerate();
	28	println!("iterate {} time(s)", self.iterations);
	29	}
	30
	31	pub fn decrease_iteration(&mut self) {
	32	self.iterations -= 1;
	33	self.regenerate();
	34	println!("iterate {} time(s)", self.iterations);
	35	}
	36
c80ba7f7 TW	37	pub fn filter_regions(&mut self) {
	38	self.grid.filter_regions();
	39	}
	40
a6b57e45	41	pub fn render(&mut self, renderer: &mut Renderer, _sprites: &SpriteManager) {
a6b57e45 TW	42	renderer.canvas().set_draw_color((64, 64, 64));
	43	let size = self.grid.cell_size;
	44	for x in 0..self.grid.width {
	45	for y in 0..self.grid.height {
	46	if self.grid.cells[x][y] {
	47	renderer.canvas().fill_rect(sdl2::rect::Rect::new(x as i32 * size as i32, y as i32 * size as i32, size as u32, size as u32)).unwrap();
	48	}
	49	}
	50	}
a6b57e45 TW	51	}
	52	}
	53
	54	////////// GRID ////////////////////////////////////////////////////////////////
	55
	56	#[derive(Default)]
	57	pub struct Grid {
	58	pub width: usize,
	59	pub height: usize,
	60	pub cell_size: usize,
	61	pub cells: Vec<Vec<bool>>,
	62	}
	63
	64	impl Grid {
	65	fn generate(iterations: u8) -> Grid {
60276654 TW	66	let cell_size = 20;
	67	let (width, height) = (2560 / cell_size, 1440 / cell_size);
	68
	69	let mut grid = Grid {
	70	cell_size,
	71	width,
	72	height,
	73	cells: vec!(vec!(true; height); width),
	74	};
	75
	76	// start with some noise
	77	// grid.simplex_noise();
	78	grid.random_noise();
a6b57e45	79
60276654 TW	80	// smooth with cellular automata
	81	grid.smooth(iterations);
	82	// grid.smooth_until_equilibrium();
	83
	84	// increase resolution
	85	for _i in 0..1 {
	86	grid = grid.subdivide();
	87	grid.smooth(iterations);
	88	}
	89
	90	grid
	91	}
	92
	93	#[allow(dead_code)]
	94	fn simplex_noise(&mut self) {
60276654 TW	95	let noise = OpenSimplex::new().set_seed(std::time::SystemTime::now().duration_since(std::time::UNIX_EPOCH).unwrap().as_secs() as u32);
	96	self.set_each(\|x, y\| noise.get([x as f64 / 12.0, y as f64 / 12.0]) > 0.055, 1);
	97	}
	98
	99	#[allow(dead_code)]
	100	fn random_noise(&mut self) {
a6b57e45	101	let mut rng = rand::thread_rng();
3fd8761b TW	102	let noise = OpenSimplex::new().set_seed(std::time::SystemTime::now().duration_since(std::time::UNIX_EPOCH).unwrap().as_secs() as u32);
	103	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
	104	// let w = self.width as f64;
	105	// self.set_each(\|_x, _y\| rng.gen_range(0, 100) > (45 + ((15 * _x) as f64 / w) as usize), 1); // opens up to the right
60276654	106	}
a6b57e45	107
60276654 TW	108	#[allow(dead_code)]
	109	fn smooth(&mut self, iterations: u8) {
	110	let distance = 1;
	111	for _i in 0..iterations {
	112	let mut next = vec!(vec!(true; self.height); self.width);
	113	for x in distance..(self.width - distance) {
	114	for y in distance..(self.height - distance) {
	115	match Grid::neighbours(&self.cells, x, y, distance) {
	116	n if n < 4 => next[x][y] = false,
	117	n if n > 4 => next[x][y] = true,
	118	_ => next[x][y] = self.cells[x][y]
	119	}
	120	}
	121	}
	122	if self.cells == next {
	123	break; // exit early
	124	} else {
	125	self.cells = next;
a6b57e45 TW	126	}
a6b57e45 TW	127	}
60276654	128	}
a6b57e45	129
60276654 TW	130	#[allow(dead_code)]
	131	fn smooth_until_equilibrium(&mut self) {
	132	let distance = 1;
	133	let mut count = 0;
	134	loop {
	135	count += 1;
	136	let mut next = vec!(vec!(true; self.height); self.width);
	137	for x in distance..(self.width - distance) {
	138	for y in distance..(self.height - distance) {
	139	match Grid::neighbours(&self.cells, x, y, distance) {
a6b57e45 TW	140	n if n < 4 => next[x][y] = false,
a6b57e45 TW	141	n if n > 4 => next[x][y] = true,
60276654	142	_ => next[x][y] = self.cells[x][y]
a6b57e45 TW	143	};
	144	}
	145	}
60276654	146	if self.cells == next {
a6b57e45 TW	147	break;
a6b57e45 TW	148	} else {
60276654	149	self.cells = next;
a6b57e45 TW	150	}
a6b57e45 TW	151	}
60276654	152	println!("{} iterations needed", count);
a6b57e45 TW	153	}
a6b57e45 TW	154
60276654	155	fn neighbours(grid: &Vec<Vec<bool>>, px: usize, py: usize, distance: usize) -> u8 {
a6b57e45	156	let mut count = 0;
60276654 TW	157	for x in (px - distance)..=(px + distance) {
60276654 TW	158	for y in (py - distance)..=(py + distance) {
a6b57e45 TW	159	if !(x == px && y == py) && grid[x][y] {
	160	count += 1;
	161	}
	162	}
	163	}
	164	count
	165	}
60276654 TW	166
	167	fn set_each<F: FnMut(usize, usize) -> bool>(&mut self, mut func: F, walls: usize) {
	168	for x in walls..(self.width - walls) {
	169	for y in walls..(self.height - walls) {
	170	self.cells[x][y] = func(x, y);
	171	}
	172	}
	173	}
	174
	175	fn subdivide(&mut self) -> Grid {
	176	let (width, height) = (self.width * 2, self.height * 2);
	177	let mut cells = vec!(vec!(true; height); width);
	178	for x in 1..(width - 1) {
	179	for y in 1..(height - 1) {
	180	cells[x][y] = self.cells[x / 2][y / 2];
	181	}
	182	}
	183	Grid {
	184	cell_size: self.cell_size / 2,
	185	width,
	186	height,
	187	cells
	188	}
	189	}
c80ba7f7 TW	190
	191	fn find_regions(&self) -> Vec<Region> {
	192	let mut regions = vec!();
	193	let mut marked = vec!(vec!(false; self.height); self.width);
	194	for x in 0..self.width {
	195	for y in 0..self.height {
	196	if !marked[x][y] {
	197	regions.push(self.get_region_at_point(x, y, &mut marked));
	198	}
	199	}
	200	}
	201	regions
	202	}
	203
	204	fn get_region_at_point(&self, x: usize, y: usize, marked: &mut Vec<Vec<bool>>) -> Region {
	205	let value = self.cells[x][y];
	206	let mut cells = vec!();
	207	let mut queue = vec!((x, y));
	208	marked[x][y] = true;
	209
	210	while let Some(p) = queue.pop() {
	211	cells.push(p);
	212	for i in &[(-1, 0), (1, 0), (0, -1), (0, 1)] {
	213	let ip = (p.0 as isize + i.0, p.1 as isize + i.1);
	214	if ip.0 >= 0 && ip.0 < self.width as isize && ip.1 >= 0 && ip.1 < self.height as isize {
	215	let up = (ip.0 as usize, ip.1 as usize);
	216	if self.cells[up.0][up.1] == value && !marked[up.0][up.1] {
	217	marked[up.0][up.1] = true;
	218	queue.push(up);
	219	}
	220	}
	221	}
	222	}
	223
	224	Region { value, cells }
	225	}
	226
	227	fn delete_region(&mut self, region: &Region) {
	228	for c in &region.cells {
	229	self.cells[c.0][c.1] = !region.value;
	230	}
	231	}
	232
	233	pub fn filter_regions(&mut self) {
	234	let min_wall_size = 0.0015;
	235	println!("grid size: ({}, {}) = {} cells", self.width, self.height, self.width * self.height);
	236	println!("min wall size: {}", (self.width * self.height) as f64 * min_wall_size);
	237
	238	// delete all smaller wall regions
	239	for r in self.find_regions().iter().filter(\|r\| r.value) {
	240	let percent = r.cells.len() as f64 / (self.width * self.height) as f64;
	241	if percent < min_wall_size {
	242	println!("delete wall region of size {}", r.cells.len());
	243	self.delete_region(r);
	244	}
	245	}
	246
	247	// delete all rooms but the largest
	248	let regions = self.find_regions(); // check again, because if a removed room contains a removed wall, the removed wall will become a room
	249	let mut rooms: Vec<&Region> = regions.iter().filter(\|r\| !r.value).collect();
	250	rooms.sort_by_key(\|r\| r.cells.len());
	251	rooms.reverse();
	252	while rooms.len() > 1 {
	253	self.delete_region(rooms.pop().unwrap());
254	}
255	}
256	}
257
258	////////// REGION //////////////////////////////////////////////////////////////
259
260	struct Region {
261	value: bool,
262	cells: Vec<(usize, usize)>,
a6b57e45	263	}