start rewrite

2024-11-25 08:18:43 -06:00 · 2023-01-19 15:41:45 +01:00 · 2023-01-19 15:41:45 +01:00 · 097bd50e4b
parent 3a446b675b
commit 097bd50e4b
27 changed files with 5 additions and 1486 deletions
--- a/.gitignore
+++ b/.gitignore
@ -12,3 +12,6 @@ Cargo.lock
 # MSVC Windows builds of rustc generate these, which store debugging information
 *.pdb
 #old source
 _src
--- a/Cargo.toml
+++ b/Cargo.toml
@ -16,7 +16,7 @@ glam = { version = "0.22", features = ["debug-glam-assert", "mint", "fast-math"]
 hashbrown = "0.13"
 noise = "0.8"
 rayon = "1.6"
-#ordered-float = "3.4"
+specs = { version =  "0.18", features = ["specs-derive"] }
 [features]
 default = []
--- a/src/game.rs
+++ b/src/game.rs
@ -1,162 +0,0 @@
 use glam::Vec2;
 use glium::Surface;
 use glium::glutin::{
  event::{Event, WindowEvent, DeviceEvent},
  event_loop::{EventLoop, ControlFlow},
 };
 use std::time::Instant;
 mod assets;
 mod display;
 mod shaders;
 mod camera;
 mod controller;
 mod world;
 mod blocks;
 mod items;
 mod options;
 mod physics;
 mod player;
 use assets::Assets;
 use display::init_display;
 use shaders::Programs;
 use camera::Camera;
 use controller::Controls;
 use world::World;
 use options::GameOptions;
 struct State {
  pub camera: Camera,
  pub first_draw: bool,
  pub controls: Controls, 
  pub world: World
 }
 impl State {
  pub fn init() -> Self {
    Self {
      first_draw: true,
      camera: Camera::default(),
      controls: Controls::default(),
      world: World::new(),
    }
  }
 }
 pub fn run() {
  log::info!("starting up");
  let event_loop = EventLoop::new();
  log::info!("initializing display");
  let display = init_display(&event_loop);
  log::info!("compiling shaders");
  let programs = Programs::compile_all(&display);
  log::info!("loading assets");
  let assets = Assets::load_all_sync(&display);
  log::info!("init game options");
  let options = GameOptions::default();
  log::info!("init game state");
  let mut state = State::init();
  state.camera.position = [0., 260., -1.];
  log::info!("game loaded");
  //=======================
  // let vertex1 = ChunkVertex { position: [-0.5, -0.5, 0.], uv: [0., 0.], normal: [0., 1., 0.] };
  // let vertex2 = ChunkVertex { position: [ 0.0,  0.5, 0.], uv: [0., 1.], normal: [0., 1., 0.] };
  // let vertex3 = ChunkVertex { position: [ 0.5, -0.5, 0.], uv: [1., 1.], normal: [0., 1., 0.] };
  // let shape = vec![vertex1, vertex2, vertex3];
  // let vertex_buffer = glium::VertexBuffer::new(&display, &shape).unwrap();
  //=======================
  let mut last_render = Instant::now();
  event_loop.run(move |event, _, control_flow| {
    *control_flow = ControlFlow::Poll;
    match event {
      // Mouse motion
      Event::DeviceEvent {
        event: DeviceEvent::MouseMotion{ delta, }, ..
      } => {
        state.controls.process_mouse_input(delta.0, delta.1);
        return
      }
      // Keyboard input
      Event::DeviceEvent { event: DeviceEvent::Key(input), .. } => {
        if let Some(key) = input.virtual_keycode {
          state.controls.process_keyboard_input(key, input.state);
        }
        return
      }
      // Window events
      Event::WindowEvent { event, .. } => {
        match event {
          WindowEvent::CloseRequested => {
            log::info!("exit requested");
            *control_flow = ControlFlow::Exit;
            return
          },
          WindowEvent::Resized(size) => {
            state.camera.update_perspective_matrix((size.width, size.height));
          },
          _ => return
        }
      },
      Event::MainEventsCleared => (),
      _ => return
    }
    //Calculate delta time
    let now = Instant::now();
    let dt = (now - last_render).as_secs_f32();
    last_render = now;
    //Update controls
    state.controls.calculate(dt).apply_to_camera(&mut state.camera);
    //Load new chunks
    state.world.update_loaded_chunks(
      Vec2::new(state.camera.position[0], state.camera.position[2]), 
      &options, 
      &display
    );
    //Start drawing
    let mut target = display.draw();
    target.clear_color_and_depth((0.5, 0.5, 1., 1.), 1.);
    //Compute camera
    if state.first_draw {
      let target_dimensions = target.get_dimensions();
      state.camera.update_perspective_matrix(target_dimensions);
    }
    let perspective = state.camera.perspective_matrix;
    let view = state.camera.view_matrix();
    //Draw chunks
    state.world.render(&mut target, &programs, &assets, perspective, view, &options);
    //Draw example triangle
    // target.draw(
    //   &vertex_buffer,
    //   glium::index::NoIndices(glium::index::PrimitiveType::TrianglesList), 
    //   &programs.chunk, 
    //   &uniform! { 
    //     model: [
    //       [1., 0., 0., 0.],
    //       [0., 1., 0., 0.],
    //       [0., 0., 1., 0.],
    //       [0., 0., 0., 1.0_f32]
    //     ],
    //     view: view,
    //     perspective: perspective,
    //     tex: Sampler(&assets.textures.block_atlas, sampler_nearest)
    //   }, 
    //   &Default::default()
    // ).unwrap();
    //Finish drawing
    target.finish().unwrap();
    state.first_draw = false;
  });
 }
--- a/src/game/assets.rs
+++ b/src/game/assets.rs
@ -1,15 +0,0 @@
 pub mod textures;
 use textures::Textures;
 pub struct Assets {
  pub textures: Textures
 }
 impl Assets {
  /// Load all assets synchronously
  pub fn load_all_sync(display: &glium::Display) -> Self {
    Self {
      textures: Textures::load_sync(display)
    }
  }
 }
--- a/src/game/assets/textures.rs
+++ b/src/game/assets/textures.rs
@ -1,103 +0,0 @@
 use std::{fs, io, path::PathBuf, sync::atomic::AtomicU16};
 use rayon::prelude::*;
 use glium::texture::{RawImage2d, SrgbTexture2d, SrgbTexture2dArray};
 //This code is terrible and has a alot of duplication
 fn load_png(file_path: &str, display: &glium::Display) -> SrgbTexture2d {
  log::info!("loading texture {}", file_path);
  //Load file
  let data = fs::read(file_path)
    .unwrap_or_else(|_| panic!("Failed to load texture: {}", file_path));
  //decode image data
  let image_data = image::load(
    io::Cursor::new(&data),
    image::ImageFormat::Png
  ).unwrap().to_rgba8();
  //Create raw glium image
  let image_dimensions = image_data.dimensions();
  let raw_image = RawImage2d::from_raw_rgba_reversed(
    &image_data.into_raw(), 
    image_dimensions
  );
  //Create texture
  SrgbTexture2d::new(display, raw_image).unwrap()
 }
 fn load_png_array(file_paths: &[PathBuf], display: &glium::Display) -> SrgbTexture2dArray {
  let counter = AtomicU16::new(0);
  let raw_images: Vec<RawImage2d<u8>> = file_paths.par_iter().enumerate().map(|(_, file_path)| {
    let fname: &str = file_path.file_name().unwrap_or_default().to_str().unwrap();
    //Load file
    let data = fs::read(file_path).expect(&format!("Failed to load texture {}", fname));
    //decode image data
    let image_data = image::load(
      io::Cursor::new(&data),
      image::ImageFormat::Png
    ).unwrap().to_rgba8();
    //Create raw glium image
    let image_dimensions = image_data.dimensions();
    let raw_image = RawImage2d::from_raw_rgba_reversed(
      &image_data.into_raw(), 
      image_dimensions
    );
    let counter = counter.fetch_add(1, std::sync::atomic::Ordering::SeqCst) + 1;
    log::info!("loaded texture {}/{}: {}", counter, file_paths.len(), fname);
    raw_image
  }).collect();
  SrgbTexture2dArray::new(display, raw_images).unwrap()
 }
 pub struct Textures {
  pub blocks: SrgbTexture2dArray
 }
 impl Textures {
  /// Load textures synchronously, one by one and upload them to the GPU
  pub fn load_sync(display: &glium::Display) -> Self {
    Self {
      blocks: load_png_array(&[
        "./assets/blocks/stone.png".into(),
        "./assets/blocks/dirt.png".into(),
        "./assets/blocks/grass_top.png".into(),
        "./assets/blocks/grass_side.png".into(),
        "./assets/blocks/sand.png".into(),
        "./assets/blocks/bedrock.png".into(),
        "./assets/blocks/wood.png".into(),
        "./assets/blocks/wood_top.png".into(),
        "./assets/blocks/leaf.png".into(),
        "./assets/blocks/torch.png".into(),
        "./assets/blocks/tall_grass.png".into(),
        "./assets/blocks/snow.png".into(),
        "./assets/blocks/grass_side_snow.png".into(),
      ], display)
    }
  }
 }
 #[derive(Clone, Copy, Debug)]
 #[repr(u8)]
 pub enum BlockTexture {
  Stone = 0,
  Dirt = 1,
  GrassTop = 2,
  GrassSide = 3,
  Sand = 4,
  Bedrock = 5,
  Wood = 6,
  WoodTop = 7,
  Leaf = 8,
  Torch = 9,
  TallGrass = 10,
  Snow = 11,
  GrassSideSnow = 12,
 }
--- a/src/game/blocks.rs
+++ b/src/game/blocks.rs
@ -1,141 +0,0 @@
 use strum::{EnumIter, IntoEnumIterator};
 use crate::game::{
  items::Item,
  assets::textures::BlockTexture,
 };
 #[derive(Clone, Copy, Debug)]
 pub enum CollisionType {
  Solid,
  Liquid,
  Ladder,
 }
 #[derive(Clone, Copy, Debug)]
 pub enum RenderType {
  OpaqueBlock,
  TranslucentBlock,
  TranslucentLiquid,
  CrossShape
 }
 #[derive(Clone, Copy, Debug)]
 pub struct BlockTextures {
  pub top: BlockTexture,
  pub bottom: BlockTexture,
  pub left: BlockTexture,
  pub right: BlockTexture,
  pub back: BlockTexture,
  pub front: BlockTexture,
 }
 impl BlockTextures {
  pub const fn all(tex: BlockTexture) -> Self {
    Self {
      top: tex,
      bottom: tex,
      left: tex,
      right: tex,
      back: tex,
      front: tex,
    }
  }
  pub const fn top_sides_bottom(top: BlockTexture, sides: BlockTexture, bottom: BlockTexture) -> Self {
    Self {
      top,
      bottom,
      left: sides,
      right: sides,
      back: sides,
      front: sides,
    }
  }
 }
 #[derive(Clone, Copy, Debug)]
 pub struct BlockDescriptor {
  pub name: &'static str,
  pub id: &'static str,
  pub collision: Option<CollisionType>,
  pub raycast_collision: bool,
  pub render: Option<(RenderType, BlockTextures)>,
  pub item: Option<Item>,
 }
 impl BlockDescriptor {
  //Not using the Default trait because this function has to be const!
  pub const fn default() -> Self {
    Self {
      name: "default",
      id: "default",
      collision: Some(CollisionType::Solid),
      raycast_collision: true,
      render: Some((RenderType::OpaqueBlock, BlockTextures::all(BlockTexture::Stone))),
      item: None
    }
  }
 }
 #[derive(Clone, Copy, Debug, EnumIter)]
 pub enum Block {
  Air,
  Stone,
  Dirt,
  Grass,
  Sand,
 }
 impl Block {
  //TODO make this O(1) with compile-time computed maps
  pub fn get_by_id(id: &str) -> Option<Self> {
    for block in Self::iter() {
      if block.descriptor().id == id {
        return Some(block)
      }
    }
    None
  }
  pub const fn descriptor(self) -> BlockDescriptor {
    match self {
      Self::Air => BlockDescriptor {
        name: "Air",
        id: "air",
        collision: None,
        raycast_collision: false,
        render: None,
        item: None,
      },
      Self::Stone => BlockDescriptor {
        name: "Stone",
        id: "stone",
        collision: Some(CollisionType::Solid),
        raycast_collision: true,
        render: Some((RenderType::OpaqueBlock, BlockTextures::all(BlockTexture::Stone))),
        item: Some(Item::StoneBlock)
      },
      Self::Dirt => BlockDescriptor {
        name: "Dirt",
        id: "dirt",
        collision: Some(CollisionType::Solid),
        raycast_collision: true,
        render: Some((RenderType::OpaqueBlock, BlockTextures::all(BlockTexture::Dirt))),
        item: Some(Item::DirtBlock)
      },
      Self::Grass => BlockDescriptor {
        name: "Grass",
        id: "grass",
        collision: Some(CollisionType::Solid),
        raycast_collision: true,
        render: Some((RenderType::OpaqueBlock, BlockTextures::top_sides_bottom(BlockTexture::GrassTop, BlockTexture::GrassSide, BlockTexture::Dirt))),
        item: Some(Item::DirtBlock)
      },
      Self::Sand => BlockDescriptor { 
        name: "Sand",
        id: "sand",
        collision: Some(CollisionType::Solid),
        raycast_collision: true,
        render: Some((RenderType::OpaqueBlock, BlockTextures::all(BlockTexture::Sand))), //this is not a sand tex
        item: Some(Item::StoneBlock)
      }
    }
  }
 }
--- a/src/game/camera.rs
+++ b/src/game/camera.rs
@ -1,157 +0,0 @@
 // Perspective/View matrix code from:
 // https://glium.github.io/glium/book/tuto-10-perspective.html
 // https://glium.github.io/glium/book/tuto-12-camera.html
 // I don't understand anything but it works
 use std::f32::consts::PI;
 pub fn calculate_forward_direction(yaw: f32, pitch: f32) -> [f32; 3] {
  [
    yaw.cos() * pitch.cos(),
    pitch.sin(),
    yaw.sin() * pitch.cos(),
  ]
 }
 fn normalize_plane(mut plane: [f32; 4]) -> [f32; 4] {
  let mag = (plane[0] * plane[0] + plane[1] * plane[1] + plane[2] * plane[2]).sqrt();
  plane[0] = plane[0] / mag;
  plane[1] = plane[1] / mag;
  plane[2] = plane[2] / mag;
  plane[3] = plane[3] / mag;
  plane
 }
 pub struct Camera {
  pub yaw: f32,
  pub pitch: f32,
  pub position: [f32; 3],
  pub direction: [f32; 3],
  pub up: [f32; 3],
  pub fov: f32,
  pub znear: f32,
  pub zfar: f32,
  pub perspective_matrix: [[f32; 4]; 4],
 }
 impl Camera {
  /// Update camera direction based on yaw/pitch
  pub fn update_direction(&mut self) {
    self.direction = calculate_forward_direction(self.yaw, self.pitch);
  }
  pub fn forward(&mut self, amount: f32) {
    self.position[0] += self.direction[0] * amount;
    self.position[1] += self.direction[1] * amount;
    self.position[2] += self.direction[2] * amount;
  }
  pub fn view_matrix(&self) -> [[f32; 4]; 4] {
    let position = self.position;
    let direction = self.direction;
    let up = self.up;
    let f = {
      let f = direction;
      let len = f[0] * f[0] + f[1] * f[1] + f[2] * f[2];
      let len = len.sqrt();
      [f[0] / len, f[1] / len, f[2] / len]
    };
    let s = [up[1] * f[2] - up[2] * f[1],
         up[2] * f[0] - up[0] * f[2],
         up[0] * f[1] - up[1] * f[0]];
    let s_norm = {
      let len = s[0] * s[0] + s[1] * s[1] + s[2] * s[2];
      let len = len.sqrt();
      [s[0] / len, s[1] / len, s[2] / len]
    };
    let u = [f[1] * s_norm[2] - f[2] * s_norm[1],
         f[2] * s_norm[0] - f[0] * s_norm[2],
         f[0] * s_norm[1] - f[1] * s_norm[0]];
    let p = [-position[0] * s_norm[0] - position[1] * s_norm[1] - position[2] * s_norm[2],
         -position[0] * u[0] - position[1] * u[1] - position[2] * u[2],
         -position[0] * f[0] - position[1] * f[1] - position[2] * f[2]];
    [
      [s_norm[0], u[0], f[0], 0.0],
      [s_norm[1], u[1], f[1], 0.0],
      [s_norm[2], u[2], f[2], 0.0],
      [p[0], p[1], p[2], 1.0],
    ]
  }
  pub fn update_perspective_matrix(&mut self, target_dimensions: (u32, u32)) {
    let znear = self.znear;
    let zfar = self.zfar;
    let fov = self.fov;
    let (width, height) = target_dimensions;
    let aspect_ratio = height as f32 / width as f32;
    let f = 1.0 / (fov / 2.0).tan();
    self.perspective_matrix = [
      [f*aspect_ratio, 0.0, 0.0,                            0.0],
      [0.0,            f,   0.0,                            0.0],
      [0.0,            0.0, (zfar+znear)/(zfar-znear),      1.0],
      [0.0,            0.0, -(2.0*zfar*znear)/(zfar-znear), 0.0],
    ];
  }
  // https://www.flipcode.com/archives/Frustum_Culling.shtml
  // https://web.archive.org/web/20070226173353/https://www2.ravensoft.com/users/ggribb/plane%20extraction.pdf
  pub fn frustum_planes(&self, normalized: bool) -> [[f32; 4]; 6] {
    let mut p_planes = [[0.0_f32; 4]; 6];
    let matrix = self.perspective_matrix;
    // Left clipping plane
    p_planes[0][0] = matrix[3][0] + matrix[0][0];
    p_planes[0][1] = matrix[3][1] + matrix[0][1];
    p_planes[0][2] = matrix[3][2] + matrix[0][2];
    p_planes[0][3] = matrix[3][3] + matrix[0][3];
    // Right clipping plane
    p_planes[1][0] = matrix[3][0] - matrix[0][0];
    p_planes[1][1] = matrix[3][1] - matrix[0][1];
    p_planes[1][2] = matrix[3][2] - matrix[0][2];
    p_planes[1][3] = matrix[3][3] - matrix[0][3];
    // Top clipping plane
    p_planes[2][0] = matrix[3][0] - matrix[1][0];
    p_planes[2][1] = matrix[3][1] - matrix[1][1];
    p_planes[2][2] = matrix[3][2] - matrix[1][2];
    p_planes[2][3] = matrix[3][3] - matrix[1][3];
    // Bottom clipping plane
    p_planes[3][0] = matrix[3][0] + matrix[1][0];
    p_planes[3][1] = matrix[3][1] + matrix[1][1];
    p_planes[3][2] = matrix[3][2] + matrix[1][2];
    p_planes[3][3] = matrix[3][3] + matrix[1][3];
    // Near clipping plane
    p_planes[4][0] = matrix[3][0] + matrix[3][0];
    p_planes[4][1] = matrix[3][1] + matrix[3][1];
    p_planes[4][2] = matrix[3][2] + matrix[3][2];
    p_planes[4][3] = matrix[3][3] + matrix[3][3];
    // Far clipping plane
    p_planes[5][0] = matrix[3][0] - matrix[3][0];
    p_planes[5][1] = matrix[3][1] - matrix[3][1];
    p_planes[5][2] = matrix[3][2] - matrix[3][2];
    p_planes[5][3] = matrix[3][3] - matrix[3][3];
    //Normalize planes
    if normalized {
      for plane in &mut p_planes {
        *plane = normalize_plane(*plane);
      }
    }
    p_planes
  }
 }
 impl Default for Camera {
  fn default() -> Self {
    Self {
      position: [0., 0., 0.],
      direction: [0., 0., 0.],
      up: [0., 1., 0.],
      fov: PI / 3.,
      zfar: 1024.,
      znear: 0.1,
      yaw: 0.,
      pitch: 0.,
      perspective_matrix: [[0.; 4]; 4]
    }
  }
 }
--- a/src/game/controller.rs
+++ b/src/game/controller.rs
@ -1,116 +0,0 @@
 use glium::glutin::event::{VirtualKeyCode, ElementState};
 use std::f32::consts::PI;
 use crate::game::camera::Camera;
 #[derive(Default, Clone, Copy)]
 pub struct InputAmounts {
  move_x: (f32, f32),
  move_y: (f32, f32),
  move_z: (f32, f32),
  look_h: f32,
  look_v: f32,
 }
 pub struct Actions {
  pub movement: [f32; 3],
  pub rotation: [f32; 2],
 }
 impl Actions {
  pub fn apply_to_camera(&self, camera: &mut Camera) {
    //Apply rotation
    camera.yaw -= self.rotation[0];
    camera.pitch -= self.rotation[1];
    camera.pitch = camera.pitch.clamp(-PI/2. + f32::EPSILON, PI/2. - f32::EPSILON);
    camera.update_direction();
    //Apply movement
    let (yaw_sin, yaw_cos) = camera.yaw.sin_cos();
    //forward movement
    camera.position[0] += yaw_cos * self.movement[2];
    camera.position[2] += yaw_sin * self.movement[2];
    //sideways movement
    camera.position[0] -= -yaw_sin * self.movement[0];
    camera.position[2] -= yaw_cos * self.movement[0];
    //up/down movement
    camera.position[1] += self.movement[1];
  }
 }
 pub struct Controls {
  inputs: InputAmounts,
  pub speed: f32,
  pub sensitivity: f32,
 }
 impl Controls {
  //TODO locking controls
  pub fn lock(&mut self) {
    todo!()
  }
  pub fn unlock(&mut self) {
    todo!()
  }
  pub fn process_mouse_input(&mut self, dx: f64, dy: f64) {
    self.inputs.look_h += dx as f32;
    self.inputs.look_v += dy as f32;
  }
  pub fn process_keyboard_input(&mut self, key: VirtualKeyCode, state: ElementState) {
    let value = match state { 
      ElementState::Pressed => 1.,
      ElementState::Released => 0.,
    };
    match key {
      VirtualKeyCode::W | VirtualKeyCode::Up => {
        self.inputs.move_z.0 = value;
      }
      VirtualKeyCode::S | VirtualKeyCode::Down => {
        self.inputs.move_z.1 = -value;
      }
      VirtualKeyCode::A | VirtualKeyCode::Left => {
        self.inputs.move_x.0 = -value;
      }
      VirtualKeyCode::D | VirtualKeyCode::Right => {
        self.inputs.move_x.1 = value;
      }
      VirtualKeyCode::Space => {
        self.inputs.move_y.0 = value;
      }
      VirtualKeyCode::LShift => {
        self.inputs.move_y.1 = -value;
      }
      _ => ()
    }
  }
  pub fn calculate(&mut self, dt: f32) -> Actions {
    let movement = {
      let move_x = self.inputs.move_x.0 + self.inputs.move_x.1;
      let move_y = self.inputs.move_y.0 + self.inputs.move_y.1;
      let move_z = self.inputs.move_z.0 + self.inputs.move_z.1;
      let magnitude = (move_x.powi(2) + move_y.powi(2) + move_z.powi(2)).sqrt();
      if magnitude == 0. {
        [0., 0., 0.]
      } else {
        [
          dt * self.speed * (move_x / magnitude), 
          dt * self.speed * (move_y / magnitude), 
          dt * self.speed * (move_z / magnitude)
        ]
      }
    };
    let rotation = [ //Do mouse inputs need to be multiplied by dt?
      self.inputs.look_h * self.sensitivity * 0.01, //* dt
      self.inputs.look_v * self.sensitivity * 0.01  //* dt
    ];
    //Only mouse related actions need to be reset
    self.inputs.look_h = 0.;
    self.inputs.look_v = 0.;
    Actions { movement, rotation }
  }
 }
 impl Default for Controls {
  fn default() -> Self {
    Self {
      inputs: Default::default(),
      speed: 40.,
      sensitivity: 1.24,
    }
  }
 }
--- a/src/game/display.rs
+++ b/src/game/display.rs
@ -1,16 +0,0 @@
 use glium::Display;
 use glium::glutin::{
  ContextBuilder,
  GlProfile,
  window::WindowBuilder,
  event_loop::EventLoop
 };
 pub fn init_display(event_loop: &EventLoop<()>) -> Display {
  let wb = WindowBuilder::new()
    .with_maximized(true);
  let cb = ContextBuilder::new()
    .with_depth_buffer(24)
    .with_gl_profile(GlProfile::Core);
  Display::new(wb, cb, event_loop).unwrap()
 }
--- a/src/game/items.rs
+++ b/src/game/items.rs
@ -1,9 +0,0 @@
 //TODO items
 #[derive(Clone, Copy, Debug)]
 pub enum Item {
  StoneBlock,
  DirtBlock,
  GrassBlock,
  SandBlock,
 }
--- a/src/game/options.rs
+++ b/src/game/options.rs
@ -1,13 +0,0 @@
 #[derive(Clone, Debug)]
 pub struct GameOptions {
  pub render_distance: u8,
  pub debug_wireframe_mode: bool,
 }
 impl Default for GameOptions {
  fn default() -> Self {
    Self {
      render_distance: if cfg!(debug_assertions) { 8 } else { 16 },
      debug_wireframe_mode: false,
    }
  }
 }
--- a/src/game/physics.rs
+++ b/src/game/physics.rs
@ -1,46 +0,0 @@
 use glam::{Vec3A, vec3a};
 use crate::game::World;
 const GRAVITY: Vec3A = vec3a(0., -1., 0.);
 pub struct BasicPhysicsActor {
  pub height: f32,
  pub gravity: Vec3A,
  pub position: Vec3A,
  pub velocity: Vec3A,
 }
 impl BasicPhysicsActor {
  pub fn new(height: f32) -> Self {
    Self {
      height,
      gravity: GRAVITY,
      position: vec3a(0., 0., 0.),
      velocity: vec3a(0., 0., 0.),
    }
  }
  pub fn update(&mut self, world: &World, dt: f32) {
    self.velocity += GRAVITY;
    self.position += self.velocity;
    loop {
      let block_pos = self.position.floor().as_ivec3();
      let block_pos_f = block_pos.as_vec3a();
      if let Some(block) = world.try_get(block_pos) {
        match block.descriptor().collision {
          Some(super::blocks::CollisionType::Solid) => {
            let position_delta = self.position - block_pos_f;
            let distance_to_zero = position_delta.abs();
            let distance_to_one = (vec3a(1., 1., 1.) - position_delta).abs();
            // let mut max_distance = 0;
            // let mut max_distance_normal = 0;
            // distance_to_one.x
            //todo compute restitution here
          }
          _ => break
        }
      } else {
        break
      }
    }
  }
 }
--- a/src/game/player.rs
+++ b/src/game/player.rs
@ -1,7 +0,0 @@
 use crate::game::camera::Camera;
 use crate::game::physics::BasicPhysicsActor;
 pub struct MainPlayer {
    pub camera: Camera,
    pub actor: BasicPhysicsActor,
 }
--- a/src/game/shaders.rs
+++ b/src/game/shaders.rs
@ -1,17 +0,0 @@
 use glium::{Display, Program};
 pub mod chunk;
 pub mod colored2d;
 pub struct Programs {
  pub colored_2d: Program,
  pub chunk: Program,
 }
 impl Programs {
  pub fn compile_all(display: &Display) -> Self {
    Self {
      colored_2d: Program::from_source(display, colored2d::VERTEX_SHADER, colored2d::FRAGMENT_SHADER, None).unwrap(),
      chunk: Program::from_source(display, chunk::VERTEX_SHADER, chunk::FRAGMENT_SHADER, None).unwrap(),
    }
  }
 }
--- a/src/game/shaders/chunk.rs
+++ b/src/game/shaders/chunk.rs
@ -1,34 +0,0 @@
 use glium::implement_vertex;
 #[derive(Clone, Copy)]
 pub struct Vertex {
  pub position: [f32; 3],
  pub normal: [f32; 3],
  pub uv: [f32; 2],
  pub tex_index: u8,
 }
 implement_vertex!(Vertex, position, normal, uv, tex_index);
 pub const VERTEX_SHADER: &str = include_str!("./glsl/chunk.vert");
 pub const FRAGMENT_SHADER: &str = include_str!("./glsl/chunk.frag");
 // pub const VERTEX_SHADER: &str = r#"
 //   #version 150 core
 //   in vec3 position;
 //   in vec3 normal;
 //   in vec2 uv;
 //   out vec3 v_normal;
 //   out vec2 v_uv;
 //   uniform mat4 perspective;
 //   uniform mat4 view;
 //   uniform mat4 model;
 //   void main() {
 //     mat4 modelview = view * model;
 //     //v_normal = transpose(inverse(mat3(modelview))) * normal;
 //     v_normal = normal;
 //     v_uv = uv;
 //     gl_Position = perspective * modelview * vec4(position, 1.0);
 //   }
 // "#;
--- a/src/game/shaders/colored2d.rs
+++ b/src/game/shaders/colored2d.rs
@ -1,10 +0,0 @@
 use glium::implement_vertex;
 #[derive(Clone, Copy)]
 pub struct Vertex {
  pub position: [f32; 2]
 }
 implement_vertex!(Vertex, position);
 pub const VERTEX_SHADER: &str = include_str!("./glsl/colored2d.vert");
 pub const FRAGMENT_SHADER: &str = include_str!("./glsl/colored2d.frag");
--- a/src/game/shaders/glsl/chunk.frag
+++ b/src/game/shaders/glsl/chunk.frag
@ -1,15 +0,0 @@
 #version 150 core
 in vec3 v_normal;
 in vec2 v_uv;
 flat in uint v_tex_index;
 out vec4 color;
 uniform sampler2DArray tex;
 void main() {
  // base color from texture
  color = texture(tex, vec3(v_uv, v_tex_index));
  //basic "lighting"
  float light = abs(v_normal.x) + .8 * abs(v_normal.y) + .6 * abs(v_normal.z);
  color *= vec4(vec3(light), 1.);
 }
--- a/src/game/shaders/glsl/chunk.vert
+++ b/src/game/shaders/glsl/chunk.vert
@ -1,19 +0,0 @@
 #version 150 core
 in vec3 position;
 in vec3 normal;
 in vec2 uv;
 in uint tex_index;
 out vec2 v_uv;
 out vec3 v_normal;
 flat out uint v_tex_index;
 uniform vec2 position_offset;
 uniform mat4 perspective;
 uniform mat4 view;
 void main() {
  v_normal = normal;
  v_tex_index = tex_index;
  v_uv = uv;
  gl_Position = perspective * view * (vec4(position, 1.0) + vec4(position_offset.x, 0., position_offset.y, 0.));
 }
--- a/src/game/shaders/glsl/colored2d.frag
+++ b/src/game/shaders/glsl/colored2d.frag
@ -1,8 +0,0 @@
 #version 150 core
 out vec4 color;
 uniform vec4 u_color;
 void main() {
  color = u_color;
 }
--- a/src/game/shaders/glsl/colored2d.vert
+++ b/src/game/shaders/glsl/colored2d.vert
@ -1,7 +0,0 @@
 #version 150 core
 in vec2 position;
 void main() {
  gl_Position = vec4(position, 0., 1.);
 }
--- a/src/game/world.rs
+++ b/src/game/world.rs
@ -1,201 +0,0 @@
 use glam::{Vec2, IVec2, IVec3, Vec3Swizzles};
 use glium::{
  Display, Frame, Surface, 
  DrawParameters, Depth, 
  DepthTest, PolygonMode,
  uniform, 
  uniforms::{
    Sampler, SamplerBehavior, 
    MinifySamplerFilter, MagnifySamplerFilter,
  }
 };
 use hashbrown::HashMap;
 use crate::game::{
  options::GameOptions,
  shaders::Programs,
  assets::Assets,
  blocks::Block,
 };
 mod chunk;
 mod thread;
 use chunk::{Chunk, ChunkState, CHUNK_SIZE};
 use thread::WorldThreading;
 const POSITIVE_X_NEIGHBOR: usize = 0;
 const NEGATIVE_X_NEIGHBOR: usize = 1;
 const POSITIVE_Z_NEIGHBOR: usize = 2;
 const NEGATIVE_Z_NEIGHBOR: usize = 3;
 const MAX_TASKS: usize = 6;
 pub struct World {
  pub chunks: HashMap<IVec2, Chunk>,
  pub thread: WorldThreading,
 }
 impl World {
  pub fn chunk_neighbors(&self, position: IVec2) -> [Option<&Chunk>; 4] {
    [
      self.chunks.get(&(position + IVec2::new(1, 0))),
      self.chunks.get(&(position - IVec2::new(1, 0))),
      self.chunks.get(&(position + IVec2::new(0, 1))),
      self.chunks.get(&(position - IVec2::new(0, 1))),
    ]
  }
  pub fn try_get(&self, position: IVec3) -> Option<Block> {
    let chunk_coord = IVec2::new(position.x, position.z) / CHUNK_SIZE as i32;
    let chunk = self.chunks.get(&chunk_coord)?;
    let block_data = chunk.block_data.as_ref()?;
    let block_position = position - (chunk_coord * CHUNK_SIZE as i32).extend(0).xzy();
    Some(
      *block_data
        .get(block_position.x as usize)?
        .get(block_position.y as usize)?
        .get(block_position.z as usize)?
    )
  }
  pub fn new() -> Self {
    Self {
      chunks: HashMap::new(),
      thread: WorldThreading::new(),
    }
  }
  pub fn render(
    &self,
    target: &mut Frame, 
    programs: &Programs,
    assets: &Assets,
    perspective: [[f32; 4]; 4],
    view: [[f32; 4]; 4],
    options: &GameOptions
  ) {
    let sampler = SamplerBehavior {
      minify_filter: MinifySamplerFilter::Linear,
      magnify_filter: MagnifySamplerFilter::Nearest,
      max_anisotropy: 8,
      ..Default::default()
    };
    let draw_parameters = DrawParameters {
      depth: Depth {
        test: DepthTest::IfLess,
        write: true,
        ..Default::default()
      },
      polygon_mode: if options.debug_wireframe_mode {
        PolygonMode::Line
      } else {
        PolygonMode::Fill
      },
      backface_culling: glium::draw_parameters::BackfaceCullingMode::CullCounterClockwise,
      ..Default::default()
    };
    for (&position, chunk) in &self.chunks {
      if let Some(mesh) = &chunk.mesh {
        target.draw(
          &mesh.vertex_buffer,
          &mesh.index_buffer,
          &programs.chunk, 
          &uniform! {
            position_offset: (position.as_vec2() * CHUNK_SIZE as f32).to_array(),
            view: view,
            perspective: perspective,
            tex: Sampler(&assets.textures.blocks, sampler)
          }, 
          &draw_parameters
        ).unwrap();
      }
    }
  }
  pub fn update_loaded_chunks(&mut self, around_position: Vec2, options: &GameOptions, display: &Display) {
    let render_dist = options.render_distance as i32 + 1;
    let inside_chunk = (around_position / CHUNK_SIZE as f32).as_ivec2();
    //Mark all chunks for unload
    for (_, chunk) in &mut self.chunks {
      chunk.desired = ChunkState::Unload;
    }
    //Load new/update chunks in range
    for x in -render_dist..=render_dist {
      for z in -render_dist..=render_dist {
        let offset = IVec2::new(x, z);
        let position = inside_chunk + offset;
        if !self.chunks.contains_key(&position) {
          self.chunks.insert(position, Chunk::new(position));
        }
        {
          //we only need mutable reference here:
          let chunk = self.chunks.get_mut(&position).unwrap();
          if x == -render_dist || z == -render_dist || x == render_dist || z == render_dist {
            chunk.desired = ChunkState::Loaded;
          } else {
            chunk.desired = ChunkState::Rendered;
          } 
        }
        let chunk = self.chunks.get(&position).unwrap();
        if self.thread.task_amount() < MAX_TASKS {
          if matches!(chunk.state, ChunkState::Nothing) && matches!(chunk.desired, ChunkState::Loaded | ChunkState::Rendered) {
            self.thread.queue_load(position);
            self.chunks.get_mut(&position).unwrap().state = ChunkState::Loading;
          } else if matches!(chunk.state, ChunkState::Loaded) && matches!(chunk.desired, ChunkState::Rendered) {
            let mut state_changed = false;
            fn all_some<'a>(x: [Option<&'a Chunk>; 4]) -> Option<[&'a Chunk; 4]> {
              Some([x[0]?, x[1]?, x[2]?, x[3]?])
            }
            if let Some(neighbors) = all_some(self.chunk_neighbors(chunk.position)) {
              if {
                neighbors[0].block_data.is_some() &&
                neighbors[1].block_data.is_some() &&
                neighbors[2].block_data.is_some() &&
                neighbors[3].block_data.is_some()
              } {
                self.thread.queue_mesh(
                  position,
                  chunk.block_data.clone().unwrap(), 
                  [
                    neighbors[0].block_data.clone().unwrap(),
                    neighbors[1].block_data.clone().unwrap(),
                    neighbors[2].block_data.clone().unwrap(),
                    neighbors[3].block_data.clone().unwrap(),
                  ]
                );
                state_changed = true;
              }
            }
            if state_changed {
              self.chunks.get_mut(&position).unwrap().state = ChunkState::Rendering;
            }
          }
        }
      }
    }
    //Unloads and state downgrades
    self.chunks.retain(|_, chunk| {
      match chunk.desired {
        // Chunk unload
        ChunkState::Unload => false,
        // Any => Nothing downgrade
        ChunkState::Nothing => {
          chunk.block_data = None;
          chunk.mesh = None;
          chunk.state = ChunkState::Nothing;
          true
        },
        //Render => Loaded downgrade
        ChunkState::Loaded if matches!(chunk.state, ChunkState::Rendering | ChunkState::Rendered) => {
          chunk.mesh = None;
          chunk.state = ChunkState::Loaded;
          true
        },
        _ => true
      }
    });
    //Apply changes from threads
    self.thread.apply_tasks(&mut self.chunks, display);
  }
 }
--- a/src/game/world/chunk.rs
+++ b/src/game/world/chunk.rs
@ -1,45 +0,0 @@
 use glam::IVec2;
 use glium::{VertexBuffer, IndexBuffer};
 use crate::game::{
  blocks::Block,
  shaders::chunk::Vertex as ChunkVertex
 };
 pub const CHUNK_SIZE: usize = 32;
 pub const CHUNK_HEIGHT: usize = 255;
 pub enum ChunkState {
  Unload,
  Nothing,
  Loading,
  Loaded,
  Rendering,
  Rendered,
 }
 pub type ChunkData = Box<[[[Block; CHUNK_SIZE]; CHUNK_HEIGHT]; CHUNK_SIZE]>;
 pub struct ChunkMesh {
  pub is_dirty: bool,
  pub vertex_buffer: VertexBuffer<ChunkVertex>,
  pub index_buffer: IndexBuffer<u32>,
 }
 pub struct Chunk {
  pub position: IVec2,
  pub block_data: Option<ChunkData>,
  pub mesh: Option<ChunkMesh>,
  pub state: ChunkState,
  pub desired: ChunkState,
 }
 impl Chunk {
  pub fn new(position: IVec2) -> Self {
    Self {
      position,
      block_data: None,
      mesh: None,
      state: ChunkState::Nothing,
      desired: ChunkState::Nothing,
    }
  }
 }
--- a/src/game/world/thread.rs
+++ b/src/game/world/thread.rs
@ -1,97 +0,0 @@
 use glam::IVec2;
 use glium::{Display, VertexBuffer, IndexBuffer, index::PrimitiveType};
 use std::{mem, thread::{self, JoinHandle}};
 use hashbrown::HashMap;
 use super::chunk::{Chunk, ChunkData, ChunkState};
 use crate::game::{shaders::chunk::Vertex as ChunkVertex, world::chunk::ChunkMesh};
 mod world_gen;
 mod mesh_gen;
 #[derive(Default)]
 pub struct WorldThreading {
  //drain_filter is not stable yet so
  //Options are needed here to take ownership, 
  //None values should never appear here!
  pub load_tasks: HashMap<IVec2, Option<JoinHandle<ChunkData>>>,
  pub mesh_tasks: HashMap<IVec2, Option<JoinHandle<(Vec<ChunkVertex>, Vec<u32>)>>>,
 }
 impl WorldThreading {
  pub fn new() -> Self {
    Self::default()
  }
  pub fn is_done(&self) -> bool {
    self.load_tasks.is_empty() && 
    self.mesh_tasks.is_empty()
  }
  pub fn task_amount(&self) -> usize {
    self.load_tasks.len() + self.mesh_tasks.len()
  }
  pub fn queue_load(&mut self, position: IVec2) {
    let handle = thread::spawn(move || {
      world_gen::generate_chunk(position, 0xdead_cafe)
    });
    if self.load_tasks.insert(position, Some(handle)).is_some() {
      log::warn!("load: discarded {}, reason: new task started", position);
    }
  }
  pub fn queue_mesh(&mut self, position: IVec2, chunk: ChunkData, neighbor_data: [ChunkData; 4]) {
    let handle = thread::spawn(move || {
      mesh_gen::generate_mesh(position, chunk, neighbor_data)
    });
    if self.mesh_tasks.insert(position, Some(handle)).is_some() {
      log::warn!("mesh: discarded {}, reason: new task started", position);
    }
  }
  pub fn apply_tasks(&mut self, chunks: &mut HashMap<IVec2, Chunk>, display: &Display) {
    //LOAD TASKS
    self.load_tasks.retain(|position, handle| {
      if !chunks.contains_key(position) {
        log::warn!("load: discarded {}, reason: chunk no longer exists", position);
        return false
      }
      if !matches!(chunks.get(position).unwrap().desired, ChunkState::Loaded | ChunkState::Rendered) {
        log::warn!("load: discarded {}, reason: state undesired", position);
        return false
      }
      if !handle.as_ref().expect("Something went terribly wrong").is_finished() {
        //task not finished yet, keep it and wait
        return true
      }
      log::info!("load: done {}", position);
      let handle = mem::take(handle).unwrap();
      let data = handle.join().unwrap();
      let chunk = chunks.get_mut(position).unwrap();
      chunk.block_data = Some(data);
      chunk.state = ChunkState::Loaded;
      false
    });
    //MESH TASKS
    self.mesh_tasks.retain(|position, handle| {
      if !chunks.contains_key(position) {
        log::warn!("mesh: discarded {}, reason: chunk no longer exists", position);
        return false
      }
      if !matches!(chunks.get(position).unwrap().desired, ChunkState::Rendered) {
        log::warn!("mesh: discarded {}, reason: state undesired", position);
        return false
      }
      if !handle.as_ref().expect("Something went terribly wrong").is_finished() {
        //task not finished yet, keep it and wait
        return true
      }
      log::info!("mesh: done {}", position);
      let handle = mem::take(handle).unwrap();
      let (shape, index) = handle.join().unwrap();
      let chunk = chunks.get_mut(position).unwrap();
      chunk.mesh = Some(ChunkMesh {
        is_dirty: false,
        vertex_buffer: VertexBuffer::new(display, &shape).expect("Failed to build VertexBuffer"),
        index_buffer: IndexBuffer::new(display, PrimitiveType::TrianglesList, &index).expect("Failed to build IndexBuffer")
      });
      chunk.state = ChunkState::Rendered;
      false
    });
  }
 }
--- a/src/game/world/thread/mesh_gen.rs
+++ b/src/game/world/thread/mesh_gen.rs
@ -1,139 +0,0 @@
 use glam::{IVec2, IVec3, Vec2, Vec3A, vec3a, vec2, ivec3};
 use strum::{EnumIter, IntoEnumIterator};
 use crate::game::{
  world::{
    POSITIVE_X_NEIGHBOR,
    NEGATIVE_X_NEIGHBOR,
    POSITIVE_Z_NEIGHBOR,
    NEGATIVE_Z_NEIGHBOR,
    chunk::{ChunkData, CHUNK_SIZE, CHUNK_HEIGHT}
  },
  shaders::chunk::Vertex, 
  blocks::Block
 };
 #[repr(usize)]
 #[derive(Clone, Copy, Debug, EnumIter)]
 pub enum CubeFace {
  Top    = 0,
  Front  = 1,
  Left   = 2,
  Right  = 3,
  Back   = 4,
  Bottom = 5,
 }
 const CUBE_FACE_VERTICES: [[Vec3A; 4]; 6] = [
  [vec3a(0., 1., 0.), vec3a(0., 1., 1.), vec3a(1., 1., 0.), vec3a(1., 1., 1.)],
  [vec3a(0., 0., 0.), vec3a(0., 1., 0.), vec3a(1., 0., 0.), vec3a(1., 1., 0.)],
  [vec3a(0., 0., 1.), vec3a(0., 1., 1.), vec3a(0., 0., 0.), vec3a(0., 1., 0.)],
  [vec3a(1., 0., 0.), vec3a(1., 1., 0.), vec3a(1., 0., 1.), vec3a(1., 1., 1.)],
  [vec3a(1., 0., 1.), vec3a(1., 1., 1.), vec3a(0., 0., 1.), vec3a(0., 1., 1.)],
  [vec3a(0., 0., 1.), vec3a(0., 0., 0.), vec3a(1., 0., 1.), vec3a(1., 0., 0.)],
 ];
 const CUBE_FACE_NORMALS: [[f32; 3]; 6] = [
  [0.,  1., 0.],
  [0.,  0., -1.],
  [-1., 0., 0.],
  [1.,  0., 0.],
  [0.,  0., 1.],
  [0., -1., 0.]
 ];
 const CUBE_FACE_INDICES: [u32; 6] = [0, 1, 2, 2, 1, 3];
 const UV_COORDS: [[f32; 2]; 4] = [
  [0., 0.],
  [0., 1.],
  [1., 0.],
  [1., 1.],
 ];
 #[derive(Default)]
 struct MeshBuilder {
  vertex_buffer: Vec<Vertex>,
  index_buffer: Vec<u32>,
  idx_counter: u32,
 }
 impl MeshBuilder {
  pub fn new() -> Self {
    Self::default()
  }
  pub fn add_face(&mut self, face: CubeFace, coord: IVec3, texture: u8) {
    let coord = coord.as_vec3a();
    let face_index = face as usize;
    //Push vertexes
    let norm = CUBE_FACE_NORMALS[face_index];
    let vert = CUBE_FACE_VERTICES[face_index];
    self.vertex_buffer.reserve(4);
    for i in 0..4 {
      self.vertex_buffer.push(Vertex {
        position: (coord + vert[i]).to_array(),
        normal: norm,
        uv: UV_COORDS[i], 
        tex_index: texture
      });
    }
    //Push indices
    self.index_buffer.extend_from_slice(&CUBE_FACE_INDICES.map(|x| x + self.idx_counter));
    self.idx_counter += 4;
  }
  pub fn finish(self) -> (Vec<Vertex>, Vec<u32>) {
    (self.vertex_buffer, self.index_buffer)
  }
 }
 pub fn generate_mesh(position: IVec2, chunk_data: ChunkData, neighbors: [ChunkData; 4]) -> (Vec<Vertex>, Vec<u32>) {
  let get_block = |pos: IVec3| -> Block {
    if pos.x < 0 {
      neighbors[NEGATIVE_X_NEIGHBOR][(CHUNK_SIZE as i32 + pos.x) as usize][pos.y as usize][pos.z as usize]
    } else if pos.x >= CHUNK_SIZE as i32 {
      neighbors[POSITIVE_X_NEIGHBOR][pos.x as usize - CHUNK_SIZE as usize][pos.y as usize][pos.z as usize]
    } else if pos.z < 0 {
      neighbors[NEGATIVE_Z_NEIGHBOR][pos.x as usize][pos.y as usize][(CHUNK_SIZE as i32 + pos.z) as usize]
    } else if pos.z >= CHUNK_SIZE as i32 {
      neighbors[POSITIVE_Z_NEIGHBOR][pos.x as usize][pos.y as usize][pos.z as usize - CHUNK_SIZE as usize]
    } else {
      chunk_data[pos.x as usize][pos.y as usize][pos.z as usize]
    }
  };
  let mut builer = MeshBuilder::new();
  for x in 0..CHUNK_SIZE {
    for y in 0..CHUNK_HEIGHT {
      for z in 0..CHUNK_SIZE {
        let coord = ivec3(x as i32, y as i32, z as i32);
        let descriptor = get_block(coord).descriptor();
        if descriptor.render.is_none() {
          continue
        }
        for face in CubeFace::iter() {
          let facing = Vec3A::from_array(CUBE_FACE_NORMALS[face as usize]).as_ivec3();
          let facing_coord = coord + facing;
          let show = {
            (facing_coord.y < 0) || 
            (facing_coord.y >= CHUNK_HEIGHT as i32) || 
            get_block(facing_coord).descriptor().render.is_none()
          };
          if show {
            let texures = descriptor.render.unwrap().1;
            let block_texture = match face {
              CubeFace::Top    => texures.top,
              CubeFace::Front  => texures.front,
              CubeFace::Left   => texures.left,
              CubeFace::Right  => texures.right,
              CubeFace::Back   => texures.back,
              CubeFace::Bottom => texures.bottom,
            };
            builer.add_face(face, coord, block_texture as u8);
          }
        }
      }
    }
  }
  builer.finish()
 }
--- a/src/game/world/thread/world_gen.rs
+++ b/src/game/world/thread/world_gen.rs
@ -1,58 +0,0 @@
 use glam::{Vec2, DVec2, IVec2};
 use noise::{NoiseFn, Perlin, Simplex, Fbm, Seedable};
 use crate::game::{
  world::chunk::{ChunkData, CHUNK_SIZE, CHUNK_HEIGHT}, 
  blocks::Block
 };
 const HEIGHTMAP_SCALE: f64 = 0.004;
 const MOUNTAINESS_SCALE: f64 = 0.0001;
 const MNT_RAMP_1: f64 = 0.5;
 const MNT_RAMP_2: f64 = 0.6;
 const MTN_VAL_SCALE: f64 = 1.233;
 const TERRAIN_HEIGHT_MIN: f64 = 60.;
 const TERRAIN_HEIGHT_MAX: f64 = 80.;
 pub fn generate_chunk(position: IVec2, seed: u32) -> ChunkData {
  let world_xz = position.as_vec2() * CHUNK_SIZE as f32;
  let mut chunk = Box::new([[[Block::Air; CHUNK_SIZE]; CHUNK_HEIGHT]; CHUNK_SIZE]);
  //generate noises
  let mut terrain_base_fbm: Fbm<Perlin> = Fbm::new(seed);
  terrain_base_fbm.octaves = 6;
  let mut mountainess_base_fbm: Fbm<Perlin> = Fbm::new(seed);
  mountainess_base_fbm.octaves = 4;
  //put everything together
  for x in 0..CHUNK_SIZE {
    for z in 0..CHUNK_SIZE {
      let point = world_xz.as_dvec2() + DVec2::from_array([x as f64, z as f64]);
      let heightmap = (terrain_base_fbm.get((point * HEIGHTMAP_SCALE).to_array()) + 1.) / 2.;
      let mountainess = MTN_VAL_SCALE * ((mountainess_base_fbm.get((point * MOUNTAINESS_SCALE).to_array()) + 1.) / 2.);
      //generate basic terrain
      let terain_height = 
        (
          TERRAIN_HEIGHT_MIN + 
          (heightmap * TERRAIN_HEIGHT_MAX * (0.1 + 1.5 * if mountainess < MNT_RAMP_1 {
            0.
          } else {
            if mountainess > MNT_RAMP_2 {
              1.
            } else {
              (mountainess - MNT_RAMP_1) / (MNT_RAMP_2 - MNT_RAMP_1) * 1.
            }
          }))
        ).floor() as usize;
      for y in 0..terain_height {
        chunk[x][y][z] = Block::Dirt;
      }
      chunk[x][terain_height][z] = Block::Grass;
    }
  }
  //return generated world
  chunk
 }
--- a/src/logging.rs
+++ b/src/logging.rs
@ -1,45 +0,0 @@
 //! Custom env_logger options and styling
 use env_logger::{fmt::Color, Builder, Env};
 use log::Level;
 use std::io::Write;
 pub fn init() {
  let mut env = Env::default();
  if cfg!(debug_assertions) {
    env = env.filter_or("RUST_LOG", "trace");
  }
  Builder::from_env(env)
    .format(|buf, record| {
      let mut level_style = buf.style();
      level_style.set_color(match record.level() {
        Level::Error => Color::Red,
        Level::Warn => Color::Yellow,
        _ => Color::Blue
      }).set_bold(true);
      let mut location_style = buf.style();
      location_style.set_bold(true);
      location_style.set_dimmed(true);
      let mut location_line_style = buf.style();
      location_line_style.set_dimmed(true);
      writeln!(
        buf,
        "{} {:<50}\t{}{}{}",
        level_style.value(match record.level() {
          Level::Error => "[e]",
          Level::Warn =>  "[w]",
          Level::Info =>  "[i]",
          Level::Debug => "[d]",
          Level::Trace => "[t]",
        }),
        format!("{}", record.args()),
        location_style.value(record.target()),
        location_line_style.value(" :"),
        location_line_style.value(record.line().unwrap_or(0))
      )
    })
    .init();
 }
--- a/src/main.rs
+++ b/src/main.rs
@ -1,7 +1,3 @@
 mod game;
 mod logging;
 fn main() {
-  logging::init();
+    
  game::run();
 }