Advent Of Code

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An unofficial home for the advent of code community on programming.dev! Other challenges are also welcome!

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.

Everybody Codes is another collection of programming puzzles with seasonal events.

EC 2025

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🦆 Everybody.Codes 2025 Quest 18 Solutions 🦆 (programming.dev)

submitted 3 weeks ago by hades@programming.dev to c/advent_of_code@programming.dev

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Quest 18: When Roots Remember

Keep top level comments as only solutions, if you want to say something other than a solution put it in a new post. (replies to comments can be whatever)
You can send code in code blocks by using three backticks, the code, and then three backticks or use something such as https://topaz.github.io/paste/ if you prefer sending it through a URL

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[–] hades@programming.dev 1 points 3 weeks ago

Rust

use regex::Regex;
use z3::{
    Optimize, Params,
    ast::{Bool, Int},
};

#[derive(Default)]
struct Plant {
    thickness: i64,
    free: Option<i64>,
    connected: Vec<(usize, i64)>,
}

fn parse_plant_spec(input: &str) -> Plant {
    let mut result = Plant::default();
    let first_re = Regex::new(r"Plant \d+ with thickness (\d+):").unwrap();
    let free_re = Regex::new(r"- free branch with thickness (\d+)").unwrap();
    let branch_re = Regex::new(r"- branch to Plant (\d+) with thickness (-?\d+)").unwrap();
    for line in input.lines() {
        if let Some((_, [thickness])) = first_re.captures(line).map(|c| c.extract()) {
            result.thickness = thickness.parse().unwrap();
        } else if let Some((_, [thickness])) = free_re.captures(line).map(|c| c.extract()) {
            result.free = Some(thickness.parse().unwrap());
        } else if let Some((_, [plant, thickness])) = branch_re.captures(line).map(|c| c.extract())
        {
            result
                .connected
                .push((plant.parse().unwrap(), thickness.parse().unwrap()));
        } else {
            panic!("cannot parse line: {line}");
        }
    }
    result
}

fn eval_plant(plants: &[Plant], number: usize, free_branches: &[i64]) -> i64 {
    let plant = &plants[number - 1];
    if plant.free.is_some() {
        assert_eq!(1, plant.thickness);
        assert_eq!(1, plant.free.unwrap());
        free_branches[number - 1]
    } else {
        let incoming = plant
            .connected
            .iter()
            .map(|&(plant_number, branch_thickness)| {
                eval_plant(plants, plant_number, free_branches) * branch_thickness
            })
            .sum::<i64>();
        if incoming >= plant.thickness {
            incoming
        } else {
            0
        }
    }
}

pub fn solve_part_1(input: &str) -> String {
    let plants = input
        .split("\n\n")
        .map(parse_plant_spec)
        .collect::<Vec<_>>();
    eval_plant(&plants, plants.len(), &vec![1; plants.len()]).to_string()
}

pub fn solve_part_2(input: &str) -> String {
    let (plants, tests) = input.split_once("\n\n\n").unwrap();
    let plants = plants
        .split("\n\n")
        .map(parse_plant_spec)
        .collect::<Vec<_>>();
    tests
        .lines()
        .map(|test| {
            eval_plant(
                &plants,
                plants.len(),
                &test
                    .split(" ")
                    .map(|v| v.parse().unwrap())
                    .collect::<Vec<i64>>(),
            )
        })
        .sum::<i64>()
        .to_string()
}

fn eval_plant_z3(plants: &[Plant], number: usize, free_branches: &[Option<Bool>]) -> Int {
    let plant = &plants[number - 1];
    if plant.free.is_some() {
        assert_eq!(1, plant.thickness);
        assert_eq!(1, plant.free.unwrap());
        free_branches[number - 1]
            .as_ref()
            .unwrap()
            .ite(&Int::from_i64(1), &Int::from_i64(0))
    } else {
        let incoming = plant
            .connected
            .iter()
            .map(|&(plant_number, branch_thickness)| {
                eval_plant_z3(plants, plant_number, free_branches) * Int::from_i64(branch_thickness)
            })
            .reduce(|a, b| a + b);
        let incoming = incoming.unwrap_or_else(|| Int::from_i64(0));
        incoming
            .ge(Int::from_i64(plant.thickness))
            .ite(&incoming, &Int::from_i64(0))
    }
}

fn maximum_achievable_brightness(plants: &[Plant]) -> i64 {
    let mut free_branches = vec![None; plants.len()];
    plants.iter().enumerate().for_each(|(i, p)| {
        if p.free.is_some() {
            free_branches[i] = Some(Bool::fresh_const("free"));
        }
    });
    let solver = Optimize::new();
    let mut params = Params::new();
    params.set_symbol("opt.maxsat_engine", "wmax");
    solver.set_params(&params);
    let brightness = eval_plant_z3(plants, plants.len(), &free_branches);
    solver.maximize(&brightness);
    match solver.check(&[]) {
        z3::SatResult::Sat => solver
            .get_model()
            .unwrap()
            .eval(&brightness, true)
            .unwrap()
            .as_i64()
            .unwrap(),
        _ => panic!("unsat"),
    }
}

pub fn solve_part_3(input: &str) -> String {
    let (plants, tests) = input.split_once("\n\n\n").unwrap();
    let plants = plants
        .split("\n\n")
        .map(parse_plant_spec)
        .collect::<Vec<_>>();
    let maximum = maximum_achievable_brightness(&plants);
    tests
        .lines()
        .map(|test| {
            eval_plant(
                &plants,
                plants.len(),
                &test
                    .split(" ")
                    .map(|v| v.parse().unwrap())
                    .collect::<Vec<i64>>(),
            )
        })
        .map(|v| if v > 0 { maximum - v } else { 0 })
        .sum::<i64>()
        .to_string()
}