valence/examples/terrain.rs

use std::collections::HashSet;
use std::net::SocketAddr;
use std::sync::atomic::{AtomicUsize, Ordering};

use log::LevelFilter;
use noise::{NoiseFn, Seedable, SuperSimplex};
use rayon::iter::ParallelIterator;
use valence::block::{BlockState, PropName, PropValue};
use valence::client::GameMode;
use valence::config::{Config, ServerListPing};
use valence::text::Color;
use valence::util::chunks_in_view_distance;
use valence::{
    async_trait, ChunkPos, ClientMut, DimensionId, Server, ShutdownResult, Text, TextFormat,
    WorldId, WorldsMut,
};
use vek::Lerp;

pub fn main() -> ShutdownResult {
    env_logger::Builder::new()
        .filter_module("valence", LevelFilter::Trace)
        .parse_default_env()
        .init();

    let seed = rand::random();

    valence::start_server(Game {
        player_count: AtomicUsize::new(0),
        density_noise: SuperSimplex::new().set_seed(seed),
        hilly_noise: SuperSimplex::new().set_seed(seed.wrapping_add(1)),
        stone_noise: SuperSimplex::new().set_seed(seed.wrapping_add(2)),
        gravel_noise: SuperSimplex::new().set_seed(seed.wrapping_add(3)),
        grass_noise: SuperSimplex::new().set_seed(seed.wrapping_add(4)),
    })
}

struct Game {
    player_count: AtomicUsize,
    density_noise: SuperSimplex,
    hilly_noise: SuperSimplex,
    stone_noise: SuperSimplex,
    gravel_noise: SuperSimplex,
    grass_noise: SuperSimplex,
}

const MAX_PLAYERS: usize = 10;

#[async_trait]
impl Config for Game {
    fn max_connections(&self) -> usize {
        // We want status pings to be successful even if the server is full.
        MAX_PLAYERS + 64
    }

    fn online_mode(&self) -> bool {
        // You'll want this to be true on real servers.
        false
    }

    async fn server_list_ping(&self, _server: &Server, _remote_addr: SocketAddr) -> ServerListPing {
        ServerListPing::Respond {
            online_players: self.player_count.load(Ordering::SeqCst) as i32,
            max_players: MAX_PLAYERS as i32,
            description: "Hello Valence!".color(Color::AQUA),
            favicon_png: Some(include_bytes!("favicon.png")),
        }
    }

    fn join(
        &self,
        _server: &Server,
        _client: ClientMut,
        worlds: WorldsMut,
    ) -> Result<WorldId, Text> {
        if let Ok(_) = self
            .player_count
            .fetch_update(Ordering::SeqCst, Ordering::SeqCst, |count| {
                (count < MAX_PLAYERS).then(|| count + 1)
            })
        {
            Ok(worlds.iter().next().unwrap().0)
        } else {
            Err("The server is full!".into())
        }
    }

    fn init(&self, _server: &Server, mut worlds: WorldsMut) {
        let (_, mut world) = worlds.create(DimensionId::default());
        world.meta.set_flat(true);
    }

    fn update(&self, server: &Server, mut worlds: WorldsMut) {
        let mut world = worlds.iter_mut().next().unwrap().1;

        let mut chunks_to_unload = HashSet::<_>::from_iter(world.chunks.iter().map(|t| t.0));

        world.clients.retain(|_, mut client| {
            if client.is_disconnected() {
                self.player_count.fetch_sub(1, Ordering::SeqCst);
                return false;
            }

            if client.created_tick() == server.current_tick() {
                client.set_game_mode(GameMode::Creative);
                client.teleport([0.0, 200.0, 0.0], 0.0, 0.0);
            }

            let dist = client.view_distance();
            let p = client.position();

            for pos in chunks_in_view_distance(ChunkPos::at(p.x, p.z), dist) {
                chunks_to_unload.remove(&pos);
                if world.chunks.get(pos).is_none() {
                    world.chunks.create(pos);
                }
            }

            true
        });

        for pos in chunks_to_unload {
            world.chunks.delete(pos);
        }

        world.chunks.par_iter_mut().for_each(|(pos, mut chunk)| {
            if chunk.created_tick() == server.current_tick() {
                for z in 0..16 {
                    for x in 0..16 {
                        let block_x = x as i64 + pos.x as i64 * 16;
                        let block_z = z as i64 + pos.z as i64 * 16;

                        let mut in_terrain = false;
                        let mut depth = 0;

                        for y in (0..chunk.height()).rev() {
                            let b = terrain_column(
                                self,
                                block_x,
                                y as i64,
                                block_z,
                                &mut in_terrain,
                                &mut depth,
                            );
                            chunk.set_block_state(x, y, z, b);
                        }

                        // Add grass
                        for y in (0..chunk.height()).rev() {
                            if chunk.get_block_state(x, y, z).is_air()
                                && chunk.get_block_state(x, y - 1, z) == BlockState::GRASS_BLOCK
                            {
                                let density = fbm(
                                    &self.grass_noise,
                                    [block_x, y as i64, block_z].map(|a| a as f64 / 5.0),
                                    4,
                                    2.0,
                                    0.7,
                                );

                                if density > 0.55 {
                                    if density > 0.7 && chunk.get_block_state(x, y + 1, z).is_air()
                                    {
                                        let upper = BlockState::TALL_GRASS
                                            .set(PropName::Half, PropValue::Upper);
                                        let lower = BlockState::TALL_GRASS
                                            .set(PropName::Half, PropValue::Lower);

                                        chunk.set_block_state(x, y + 1, z, upper);
                                        chunk.set_block_state(x, y, z, lower);
                                    } else {
                                        chunk.set_block_state(x, y, z, BlockState::GRASS);
                                    }
                                }
                            }
                        }
                    }
                }
            }
        });
    }
}

fn terrain_column(
    g: &Game,
    x: i64,
    y: i64,
    z: i64,
    in_terrain: &mut bool,
    depth: &mut u32,
) -> BlockState {
    const WATER_HEIGHT: i64 = 55;

    if has_terrain_at(g, x, y, z) {
        let gravel_height = WATER_HEIGHT
            - (noise01(&g.gravel_noise, [x, y, z].map(|a| a as f64 / 10.0)) * 6.0).round() as i64;

        if *in_terrain {
            if *depth > 0 {
                *depth -= 1;
                if y < gravel_height {
                    BlockState::GRAVEL
                } else {
                    BlockState::DIRT
                }
            } else {
                BlockState::STONE
            }
        } else {
            *in_terrain = true;
            let n = noise01(&g.stone_noise, [x, y, z].map(|a| a as f64 / 15.0));

            *depth = (n * 5.0).round() as u32;

            if y < gravel_height {
                BlockState::GRAVEL
            } else if y < WATER_HEIGHT - 1 {
                BlockState::DIRT
            } else {
                BlockState::GRASS_BLOCK
            }
        }
    } else {
        *in_terrain = false;
        *depth = 0;
        if y < WATER_HEIGHT {
            BlockState::WATER
        } else {
            BlockState::AIR
        }
    }
}

fn has_terrain_at(g: &Game, x: i64, y: i64, z: i64) -> bool {
    let hilly = Lerp::lerp_unclamped(
        0.1,
        1.0,
        noise01(&g.hilly_noise, [x, y, z].map(|a| a as f64 / 400.0)).powi(2),
    );

    let lower = 10.0 + 150.0 * hilly;
    let upper = lower + 100.0 * hilly;

    if y as f64 <= lower {
        return true;
    } else if y as f64 >= upper {
        return false;
    }

    let density = 1.0 - lerpstep(lower, upper, y as f64);

    let n = fbm(
        &g.density_noise,
        [x, y, z].map(|a| a as f64 / 100.0),
        4,
        2.0,
        0.5,
    );
    n < density
}

fn lerpstep(edge0: f64, edge1: f64, x: f64) -> f64 {
    if x <= edge0 {
        0.0
    } else if x >= edge1 {
        1.0
    } else {
        (x - edge0) / (edge1 - edge0)
    }
}

fn fbm(noise: &SuperSimplex, p: [f64; 3], octaves: u32, lacunarity: f64, persistence: f64) -> f64 {
    let mut freq = 1.0;
    let mut amp = 1.0;
    let mut amp_sum = 0.0;
    let mut sum = 0.0;

    for _ in 0..octaves {
        let n = noise01(noise, p.map(|a| a * freq));
        sum += n * amp;
        amp_sum += amp;

        freq *= lacunarity;
        amp *= persistence;
    }

    // Scale the output to [0, 1]
    sum / amp_sum
}

fn noise01(noise: &SuperSimplex, xyz: [f64; 3]) -> f64 {
    (noise.get(xyz) + 1.0) / 2.0
}