roguelike-game/src/map_builders/maze.rs

use std::cmp::{max, min};
use std::collections::HashMap;

use rltk::RandomNumberGenerator;
use specs::prelude::*;

use super::{
    generate_voronoi_spawn_regions, remove_unreachable_areas_returning_most_distant, MapBuilder,
};
use crate::{spawner, Map, Position, TileType, SHOW_MAPGEN_VISUALIZER};

pub struct MazeBuilder {
    map: Map,
    starting_position: Position,
    depth: i32,
    history: Vec<Map>,
    noise_areas: HashMap<i32, Vec<usize>>,
    spawn_list: Vec<(usize, String)>,
}

impl MapBuilder for MazeBuilder {
    fn get_map(&self) -> Map {
        self.map.clone()
    }

    fn get_starting_position(&self) -> Position {
        self.starting_position
    }

    fn get_snapshot_history(&self) -> Vec<Map> {
        self.history.clone()
    }

    fn build_map(&mut self) {
        self.build();
    }

    fn take_snapshot(&mut self) {
        if SHOW_MAPGEN_VISUALIZER {
            let mut snapshot = self.map.clone();
            for v in snapshot.revealed_tiles.iter_mut() {
                *v = true;
            }
            self.history.push(snapshot);
        }
    }

    fn get_spawn_list(&self) -> &Vec<(usize, String)> {
        &self.spawn_list
    }
}

impl MazeBuilder {
    pub fn new(new_depth: i32) -> MazeBuilder {
        MazeBuilder {
            map: Map::new(new_depth),
            starting_position: Position::default(),
            depth: new_depth,
            history: Vec::new(),
            noise_areas: HashMap::new(),
            spawn_list: Vec::new(),
        }
    }

    #[allow(clippy::map_entry)]
    fn build(&mut self) {
        let mut rng = RandomNumberGenerator::new();

        // Maze gen
        let mut maze = Grid::new(
            (self.map.width / 2) - 2,
            (self.map.height / 2) - 2,
            &mut rng,
        );
        maze.generate_maze(self);

        self.starting_position = Position { x: 2, y: 2 };
        let start_idx = self
            .map
            .xy_idx(self.starting_position.x, self.starting_position.y);
        self.take_snapshot();

        // Find all tiles we can reach from the starting point
        let exit_tile = remove_unreachable_areas_returning_most_distant(&mut self.map, start_idx);
        self.take_snapshot();

        // Place the stairs
        self.map.tiles[exit_tile] = TileType::DownStairs;
        self.take_snapshot();

        // Now we build a noise map for use in spawning entities later
        self.noise_areas = generate_voronoi_spawn_regions(&self.map, &mut rng);
    }
}

const TOP: usize = 0;
const RIGHT: usize = 1;
const BOTTOM: usize = 2;
const LEFT: usize = 3;

#[derive(Copy, Clone)]
struct Cell {
    row: i32,
    column: i32,
    walls: [bool; 4],
    visited: bool,
}

impl Cell {
    fn new(row: i32, column: i32) -> Cell {
        Cell {
            row,
            column,
            walls: [true, true, true, true],
            visited: false,
        }
    }

    fn remove_walls(&mut self, next: &mut Cell) {
        let x = self.column - next.column;
        let y = self.row - next.row;

        if x == 1 {
            self.walls[LEFT] = false;
            next.walls[RIGHT] = false;
        } else if x == -1 {
            self.walls[RIGHT] = false;
            next.walls[LEFT] = false;
        } else if y == 1 {
            self.walls[TOP] = false;
            next.walls[BOTTOM] = false;
        } else if y == -1 {
            self.walls[BOTTOM] = false;
            next.walls[TOP] = false;
        }
    }
}

struct Grid<'a> {
    width: i32,
    height: i32,
    cells: Vec<Cell>,
    backtrace: Vec<usize>,
    current: usize,
    rng: &'a mut RandomNumberGenerator,
}

impl<'a> Grid<'a> {
    fn new(width: i32, height: i32, rng: &mut RandomNumberGenerator) -> Grid {
        let mut grid = Grid {
            width,
            height,
            cells: Vec::new(),
            backtrace: Vec::new(),
            current: 0,
            rng,
        };

        for row in 0..height {
            for column in 0..width {
                grid.cells.push(Cell::new(row, column));
            }
        }

        grid
    }

    fn calculate_index(&self, row: i32, column: i32) -> i32 {
        if row < 0 || column < 0 || column > self.width - 1 || row > self.height - 1 {
            -1
        } else {
            column + (row * self.width)
        }
    }

    fn get_available_neighbors(&self) -> Vec<usize> {
        let mut neighbors: Vec<usize> = Vec::new();

        let current_row = self.cells[self.current].row;
        let current_column = self.cells[self.current].column;

        let neighbor_indices: [i32; 4] = [
            self.calculate_index(current_row - 1, current_column),
            self.calculate_index(current_row, current_column + 1),
            self.calculate_index(current_row + 1, current_column),
            self.calculate_index(current_row, current_column - 1),
        ];

        for i in neighbor_indices.iter() {
            if *i != -1 && !self.cells[*i as usize].visited {
                neighbors.push(*i as usize);
            }
        }

        neighbors
    }

    fn find_next_cell(&mut self) -> Option<usize> {
        let neighbors = self.get_available_neighbors();
        if !neighbors.is_empty() {
            return if neighbors.len() == 1 {
                Some(neighbors[0])
            } else {
                Some(neighbors[(self.rng.roll_dice(1, neighbors.len() as i32) - 1) as usize])
            };
        }

        None
    }

    fn generate_maze(&mut self, generator: &mut MazeBuilder) {
        let mut i = 0;
        loop {
            self.cells[self.current].visited = true;

            match self.find_next_cell() {
                Some(next) => {
                    self.cells[next].visited = true;
                    self.backtrace.push(self.current);

                    //   __lower_part__      __higher_part_
                    //   /            \      /            \
                    // --------cell1------ | cell2-----------
                    let (lower_part, higher_part) =
                        self.cells.split_at_mut(max(self.current, next));
                    let cell1 = &mut lower_part[min(self.current, next)];
                    let cell2 = &mut higher_part[0];

                    cell1.remove_walls(cell2);
                    self.current = next;
                }
                None => {
                    if !self.backtrace.is_empty() {
                        self.current = self.backtrace[0];
                        self.backtrace.remove(0);
                    } else {
                        break;
                    }
                }
            }

            if i % 50 == 0 {
                self.copy_to_map(&mut generator.map);
                generator.take_snapshot();
            }
            i += 1;
        }
    }

    fn copy_to_map(&self, map: &mut Map) {
        // Clear the map
        for i in map.tiles.iter_mut() {
            *i = TileType::Wall;
        }

        for cell in self.cells.iter() {
            let x = cell.column + 1;
            let y = cell.row + 1;
            let idx = map.xy_idx(x * 2, y * 2);

            map.tiles[idx] = TileType::Floor;

            if !cell.walls[TOP] {
                map.tiles[idx - map.width as usize] = TileType::Floor;
            }
            if !cell.walls[RIGHT] {
                map.tiles[idx + 1] = TileType::Floor
            }
            if !cell.walls[BOTTOM] {
                map.tiles[idx + map.width as usize] = TileType::Floor
            }
            if !cell.walls[LEFT] {
                map.tiles[idx - 1] = TileType::Floor
            }
        }
    }
}
Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`use std::cmp::{max, min};`
			`use std::collections::HashMap;`

Reorder use statements 2021-12-10 20:16:48 -05:00			`use rltk::RandomNumberGenerator;`
			`use specs::prelude::*;`

			`use super::{`
			`generate_voronoi_spawn_regions, remove_unreachable_areas_returning_most_distant, MapBuilder,`
			`};`
			`use crate::{spawner, Map, Position, TileType, SHOW_MAPGEN_VISUALIZER};`

Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`pub struct MazeBuilder {`
			`map: Map,`
			`starting_position: Position,`
			`depth: i32,`
			`history: Vec<Map>,`
			`noise_areas: HashMap<i32, Vec<usize>>,`
Refactor entity (Enemy, Item, Equipment) spawning 2021-12-10 16:34:11 -05:00			`spawn_list: Vec<(usize, String)>,`
Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`}`

			`impl MapBuilder for MazeBuilder {`
			`fn get_map(&self) -> Map {`
			`self.map.clone()`
			`}`

			`fn get_starting_position(&self) -> Position {`
			`self.starting_position`
			`}`

			`fn get_snapshot_history(&self) -> Vec<Map> {`
			`self.history.clone()`
			`}`

Cleanup some code for the start of Section 4.12 2021-12-10 11:30:58 -05:00			`fn build_map(&mut self) {`
			`self.build();`
			`}`

Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`fn take_snapshot(&mut self) {`
			`if SHOW_MAPGEN_VISUALIZER {`
			`let mut snapshot = self.map.clone();`
			`for v in snapshot.revealed_tiles.iter_mut() {`
			`*v = true;`
			`}`
			`self.history.push(snapshot);`
			`}`
			`}`
Refactor entity (Enemy, Item, Equipment) spawning 2021-12-10 16:34:11 -05:00
			`fn get_spawn_list(&self) -> &Vec<(usize, String)> {`
			`&self.spawn_list`
			`}`
Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`}`

			`impl MazeBuilder {`
			`pub fn new(new_depth: i32) -> MazeBuilder {`
			`MazeBuilder {`
			`map: Map::new(new_depth),`
Refactor entity (Enemy, Item, Equipment) spawning 2021-12-10 16:34:11 -05:00			`starting_position: Position::default(),`
Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`depth: new_depth,`
			`history: Vec::new(),`
			`noise_areas: HashMap::new(),`
Refactor entity (Enemy, Item, Equipment) spawning 2021-12-10 16:34:11 -05:00			`spawn_list: Vec::new(),`
Complete section 4.7, using maze generation to build a map 2021-12-06 15:49:40 -05:00			`}`
			`}`

			`#[allow(clippy::map_entry)]`
			`fn build(&mut self) {`
			`let mut rng = RandomNumberGenerator::new();`

			`// Maze gen`
			`let mut maze = Grid::new(`
			`(self.map.width / 2) - 2,`
			`(self.map.height / 2) - 2,`
			`&mut rng,`
			`);`
			`maze.generate_maze(self);`

			`self.starting_position = Position { x: 2, y: 2 };`
			`let start_idx = self`
			`.map`
			`.xy_idx(self.starting_position.x, self.starting_position.y);`
			`self.take_snapshot();`

			`// Find all tiles we can reach from the starting point`
			`let exit_tile = remove_unreachable_areas_returning_most_distant(&mut self.map, start_idx);`
			`self.take_snapshot();`

			`// Place the stairs`
			`self.map.tiles[exit_tile] = TileType::DownStairs;`
			`self.take_snapshot();`

			`// Now we build a noise map for use in spawning entities later`
			`self.noise_areas = generate_voronoi_spawn_regions(&self.map, &mut rng);`
			`}`
			`}`

			`const TOP: usize = 0;`
			`const RIGHT: usize = 1;`
			`const BOTTOM: usize = 2;`
			`const LEFT: usize = 3;`

			`#[derive(Copy, Clone)]`
			`struct Cell {`
			`row: i32,`
			`column: i32,`
			`walls: [bool; 4],`
			`visited: bool,`
			`}`

			`impl Cell {`
			`fn new(row: i32, column: i32) -> Cell {`
			`Cell {`
			`row,`
			`column,`
			`walls: [true, true, true, true],`
			`visited: false,`
			`}`
			`}`

			`fn remove_walls(&mut self, next: &mut Cell) {`
			`let x = self.column - next.column;`
			`let y = self.row - next.row;`

			`if x == 1 {`
			`self.walls[LEFT] = false;`
			`next.walls[RIGHT] = false;`
			`} else if x == -1 {`
			`self.walls[RIGHT] = false;`
			`next.walls[LEFT] = false;`
			`} else if y == 1 {`
			`self.walls[TOP] = false;`
			`next.walls[BOTTOM] = false;`
			`} else if y == -1 {`
			`self.walls[BOTTOM] = false;`
			`next.walls[TOP] = false;`
			`}`
			`}`
			`}`

			`struct Grid<'a> {`
			`width: i32,`
			`height: i32,`
			`cells: Vec<Cell>,`
			`backtrace: Vec<usize>,`
			`current: usize,`
			`rng: &'a mut RandomNumberGenerator,`
			`}`

			`impl<'a> Grid<'a> {`
			`fn new(width: i32, height: i32, rng: &mut RandomNumberGenerator) -> Grid {`
			`let mut grid = Grid {`
			`width,`
			`height,`
			`cells: Vec::new(),`
			`backtrace: Vec::new(),`
			`current: 0,`
			`rng,`
			`};`

			`for row in 0..height {`
			`for column in 0..width {`
			`grid.cells.push(Cell::new(row, column));`
			`}`
			`}`

			`grid`
			`}`

			`fn calculate_index(&self, row: i32, column: i32) -> i32 {`
			`if row < 0 \|\| column < 0 \|\| column > self.width - 1 \|\| row > self.height - 1 {`
			`-1`
			`} else {`
			`column + (row * self.width)`
			`}`
			`}`

			`fn get_available_neighbors(&self) -> Vec<usize> {`
			`let mut neighbors: Vec<usize> = Vec::new();`

			`let current_row = self.cells[self.current].row;`
			`let current_column = self.cells[self.current].column;`

			`let neighbor_indices: [i32; 4] = [`
			`self.calculate_index(current_row - 1, current_column),`
			`self.calculate_index(current_row, current_column + 1),`
			`self.calculate_index(current_row + 1, current_column),`
			`self.calculate_index(current_row, current_column - 1),`
			`];`

			`for i in neighbor_indices.iter() {`
			`if i != -1 && !self.cells[i as usize].visited {`
			`neighbors.push(*i as usize);`
			`}`
			`}`

			`neighbors`
			`}`

			`fn find_next_cell(&mut self) -> Option<usize> {`
			`let neighbors = self.get_available_neighbors();`
			`if !neighbors.is_empty() {`
			`return if neighbors.len() == 1 {`
			`Some(neighbors[0])`
			`} else {`
			`Some(neighbors[(self.rng.roll_dice(1, neighbors.len() as i32) - 1) as usize])`
			`};`
			`}`

			`None`
			`}`

			`fn generate_maze(&mut self, generator: &mut MazeBuilder) {`
			`let mut i = 0;`
			`loop {`
			`self.cells[self.current].visited = true;`

			`match self.find_next_cell() {`
			`Some(next) => {`
			`self.cells[next].visited = true;`
			`self.backtrace.push(self.current);`

			`// __lower_part__ __higher_part_`
			`// / \ / \`
			`// --------cell1------ \| cell2-----------`
			`let (lower_part, higher_part) =`
			`self.cells.split_at_mut(max(self.current, next));`
			`let cell1 = &mut lower_part[min(self.current, next)];`
			`let cell2 = &mut higher_part[0];`

			`cell1.remove_walls(cell2);`
			`self.current = next;`
			`}`
			`None => {`
			`if !self.backtrace.is_empty() {`
			`self.current = self.backtrace[0];`
			`self.backtrace.remove(0);`
			`} else {`
			`break;`
			`}`
			`}`
			`}`

			`if i % 50 == 0 {`
			`self.copy_to_map(&mut generator.map);`
			`generator.take_snapshot();`
			`}`
			`i += 1;`
			`}`
			`}`

			`fn copy_to_map(&self, map: &mut Map) {`
			`// Clear the map`
			`for i in map.tiles.iter_mut() {`
			`*i = TileType::Wall;`
			`}`

			`for cell in self.cells.iter() {`
			`let x = cell.column + 1;`
			`let y = cell.row + 1;`
			`let idx = map.xy_idx(x * 2, y * 2);`

			`map.tiles[idx] = TileType::Floor;`

			`if !cell.walls[TOP] {`
			`map.tiles[idx - map.width as usize] = TileType::Floor;`
			`}`
			`if !cell.walls[RIGHT] {`
			`map.tiles[idx + 1] = TileType::Floor`
			`}`
			`if !cell.walls[BOTTOM] {`
			`map.tiles[idx + map.width as usize] = TileType::Floor`
			`}`
			`if !cell.walls[LEFT] {`
			`map.tiles[idx - 1] = TileType::Floor`
			`}`
			`}`
			`}`
			`}`