this post was submitted on 16 Dec 2024
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Advent Of Code

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Advent of Code is an annual Advent calendar of small programming puzzles for a variety of skill sets and skill levels that can be solved in any programming language you like.

AoC 2024

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Day 16: Reindeer Maze

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Rust

Dijkstra's algorithm. While the actual shortest path was not needed in part 1, only the distance, in part 2 the path is saved in the parent hashmap, and crucially, if we encounter two paths with the same distance, both parent nodes are saved. This ensures we end up with all shortest paths in the end.

Solution

use std::cmp::{Ordering, Reverse};

use euclid::{default::*, vec2};
use priority_queue::PriorityQueue;
use rustc_hash::{FxHashMap, FxHashSet};

const DIRS: [Vector2D<i32>; 4] = [vec2(1, 0), vec2(0, 1), vec2(-1, 0), vec2(0, -1)];

type Node = (Point2D<i32>, u8);

fn parse(input: &str) -> (Vec<Vec<bool>>, Point2D<i32>, Point2D<i32>) {
    let mut start = None;
    let mut end = None;
    let mut field = Vec::new();
    for (y, l) in input.lines().enumerate() {
        let mut row = Vec::new();
        for (x, b) in l.bytes().enumerate() {
            if b == b'S' {
                start = Some(Point2D::new(x, y).to_i32());
            } else if b == b'E' {
                end = Some(Point2D::new(x, y).to_i32());
            }
            row.push(b == b'#');
        }
        field.push(row);
    }
    (field, start.unwrap(), end.unwrap())
}

fn adj(field: &[Vec<bool>], (v, dir): Node) -> Vec<(Node, u32)> {
    let mut adj = Vec::with_capacity(3);
    let next = v + DIRS[dir as usize];
    if !field[next.y as usize][next.x as usize] {
        adj.push(((next, dir), 1));
    }
    adj.push(((v, (dir + 1) % 4), 1000));
    adj.push(((v, (dir + 3) % 4), 1000));
    adj
}

fn shortest_path_length(field: &[Vec<bool>], start: Node, end: Point2D<i32>) -> u32 {
    let mut dist: FxHashMap<Node, u32> = FxHashMap::default();
    dist.insert(start, 0);
    let mut pq: PriorityQueue<Node, Reverse<u32>> = PriorityQueue::new();
    pq.push(start, Reverse(0));
    while let Some((v, _)) = pq.pop() {
        for (w, weight) in adj(field, v) {
            let dist_w = dist.get(&w).copied().unwrap_or(u32::MAX);
            let new_dist = dist[&v] + weight;
            if dist_w > new_dist {
                dist.insert(w, new_dist);
                pq.push_increase(w, Reverse(new_dist));
            }
        }
    }
    // Shortest distance to end, regardless of final direction
    (0..4).map(|dir| dist[&(end, dir)]).min().unwrap()
}

fn part1(input: String) {
    let (field, start, end) = parse(&input);
    let distance = shortest_path_length(&field, (start, 0), end);
    println!("{distance}");
}

fn shortest_path_tiles(field: &[Vec<bool>], start: Node, end: Point2D<i32>) -> u32 {
    let mut parents: FxHashMap<Node, Vec<Node>> = FxHashMap::default();
    let mut dist: FxHashMap<Node, u32> = FxHashMap::default();
    dist.insert(start, 0);
    let mut pq: PriorityQueue<Node, Reverse<u32>> = PriorityQueue::new();
    pq.push(start, Reverse(0));
    while let Some((v, _)) = pq.pop() {
        for (w, weight) in adj(field, v) {
            let dist_w = dist.get(&w).copied().unwrap_or(u32::MAX);
            let new_dist = dist[&v] + weight;
            match dist_w.cmp(&new_dist) {
                Ordering::Greater => {
                    parents.insert(w, vec![v]);
                    dist.insert(w, new_dist);
                    pq.push_increase(w, Reverse(new_dist));
                }
                // Remember both parents if distance is equal
                Ordering::Equal => parents.get_mut(&w).unwrap().push(v),
                Ordering::Less => {}
            }
        }
    }
    let mut path_tiles: FxHashSet<Point2D<i32>> = FxHashSet::default();
    path_tiles.insert(end);

    // Shortest distance to end, regardless of final direction
    let shortest_dist = (0..4).map(|dir| dist[&(end, dir)]).min().unwrap();
    for dir in 0..4 {
        if dist[&(end, dir)] == shortest_dist {
            collect_tiles(&parents, &mut path_tiles, (end, dir));
        }
    }
    path_tiles.len() as u32
}

fn collect_tiles(
    parents: &FxHashMap<Node, Vec<Node>>,
    tiles: &mut FxHashSet<Point2D<i32>>,
    cur: Node,
) {
    if let Some(pars) = parents.get(&cur) {
        for p in pars {
            tiles.insert(p.0);
            collect_tiles(parents, tiles, *p);
        }
    }
}

fn part2(input: String) {
    let (field, start, end) = parse(&input);
    let tiles = shortest_path_tiles(&field, (start, 0), end);
    println!("{tiles}");
}

util::aoc_main!();

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