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base: xevion:v0.35.0
Branches Tags
xevion:master xevion:dependabot/cargo/rust-minor-01c68be507 xevion:dependabot/cargo/rust-patches-eeb485b1b5 xevion:server xevion:test
xevion:v0.81.1 xevion:v0.81.0 xevion:v0.80.3 xevion:v0.80.2 xevion:v0.80.1 xevion:v0.80.0 xevion:v0.79.2 xevion:v0.79.1 xevion:v0.79.0 xevion:v0.78.5 xevion:v0.78.4 xevion:v0.78.3 xevion:v0.78.2 xevion:v0.78.1 xevion:v0.78.0 xevion:v0.77.1 xevion:v0.77.0 xevion:v0.76.1 xevion:v0.76.0 xevion:v0.74.6 xevion:v0.74.5 xevion:v0.74.8 xevion:v0.74.7 xevion:v0.74.9 xevion:v0.74.11 xevion:v0.74.10 xevion:v0.75.1 xevion:v0.75.0 xevion:v0.52.1 xevion:v0.53.0 xevion:v0.53.1 xevion:v0.54.0 xevion:v0.55.0 xevion:v0.55.1 xevion:v0.55.2 xevion:v0.55.3 xevion:v0.56.0 xevion:v0.56.1 xevion:v0.56.2 xevion:v0.56.3 xevion:v0.56.4 xevion:v0.57.0 xevion:v0.57.1 xevion:v0.58.0 xevion:v0.59.0 xevion:v0.59.1 xevion:v0.60.0 xevion:v0.60.1 xevion:v0.60.2 xevion:v0.60.3 xevion:v0.61.0 xevion:v0.61.1 xevion:v0.62.0 xevion:v0.63.0 xevion:v0.64.0 xevion:v0.64.1 xevion:v0.65.0 xevion:v0.66.0 xevion:v0.67.0 xevion:v0.67.1 xevion:v0.68.0 xevion:v0.68.1 xevion:v0.70.0 xevion:v0.69.1 xevion:v0.69.0 xevion:v0.71.1 xevion:v0.71.0 xevion:v0.72.0 xevion:v0.73.0 xevion:v0.74.1 xevion:v0.74.0 xevion:v0.74.3 xevion:v0.74.2 xevion:v0.74.4 xevion:v0.36.0 xevion:v0.37.0 xevion:v0.37.1 xevion:v0.37.2 xevion:v0.38.0 xevion:v0.39.0 xevion:v0.39.1 xevion:v0.39.2 xevion:v0.39.3 xevion:v0.40.0 xevion:v0.40.1 xevion:v0.41.0 xevion:v0.41.1 xevion:v0.41.2 xevion:v0.41.3 xevion:v0.42.0 xevion:v0.42.1 xevion:v0.43.0 xevion:v0.44.0 xevion:v0.44.1 xevion:v0.44.2 xevion:v0.44.3 xevion:v0.44.4 xevion:v0.44.5 xevion:v0.45.0 xevion:v0.45.1 xevion:v0.46.0 xevion:v0.47.0 xevion:v0.47.1 xevion:v0.48.0 xevion:v0.48.1 xevion:v0.48.2 xevion:v0.48.3 xevion:v0.48.4 xevion:v0.48.5 xevion:v0.48.6 xevion:v0.48.7 xevion:v0.48.8 xevion:v0.49.0 xevion:v0.49.1 xevion:v0.50.0 xevion:v0.50.1 xevion:v0.51.0 xevion:v0.52.0 xevion:v0.34.10 xevion:v0.35.0 xevion:v0.23.10 xevion:v0.23.11 xevion:v0.23.12 xevion:v0.23.13 xevion:v0.23.14 xevion:v0.23.15 xevion:v0.23.16 xevion:v0.24.0 xevion:v0.24.1 xevion:v0.24.2 xevion:v0.24.3 xevion:v0.25.0 xevion:v0.34.9 xevion:v0.26.1 xevion:v0.26.2 xevion:v0.26.3 xevion:v0.26.4 xevion:v0.27.0 xevion:v0.27.1 xevion:v0.28.0 xevion:v0.28.1 xevion:v0.30.0 xevion:v0.29.0 xevion:v0.30.1 xevion:v0.30.2 xevion:v0.31.0 xevion:v0.31.1 xevion:v0.31.2 xevion:v0.31.3 xevion:v0.31.4 xevion:v0.31.5 xevion:v0.32.0 xevion:v0.32.1 xevion:v0.33.0 xevion:v0.34.0 xevion:v0.34.1 xevion:v0.34.2 xevion:v0.34.3 xevion:v0.34.4 xevion:v0.34.5 xevion:v0.34.6 xevion:v0.34.7 xevion:v0.34.8 xevion:v0.26.0 xevion:v0.23.8 xevion:v0.23.9 xevion:v0.17.9 xevion:v0.17.10 xevion:v0.17.11 xevion:v0.17.12 xevion:v0.17.13 xevion:v0.17.14 xevion:v0.23.7 xevion:v0.17.17 xevion:v0.17.16 xevion:v0.18.1 xevion:v0.18.0 xevion:v0.18.2 xevion:v0.18.3 xevion:v0.18.5 xevion:v0.18.4 xevion:v0.18.6 xevion:v0.18.7 xevion:v0.18.8 xevion:v0.18.9 xevion:v0.18.10 xevion:v0.18.11 xevion:v0.18.12 xevion:v0.18.13 xevion:v0.18.14 xevion:v0.18.15 xevion:v0.18.16 xevion:v0.19.0 xevion:v0.20.0 xevion:v0.21.0 xevion:v0.22.0 xevion:v0.22.1 xevion:v0.22.2 xevion:v0.22.3 xevion:v0.22.4 xevion:v0.23.0 xevion:v0.23.1 xevion:v0.23.2 xevion:v0.23.3 xevion:v0.23.4 xevion:v0.23.5 xevion:v0.23.6 xevion:v0.17.15 xevion:v0.17.7 xevion:v0.17.8 xevion:v0.6.9 xevion:v0.6.8 xevion:v0.6.7 xevion:v0.6.6 xevion:v0.17.5 xevion:v0.6.4 xevion:v0.6.3 xevion:v0.6.2 xevion:v0.6.18 xevion:v0.6.17 xevion:v0.6.16 xevion:v0.6.15 xevion:v0.6.14 xevion:v0.6.13 xevion:v0.6.12 xevion:v0.6.11 xevion:v0.6.10 xevion:v0.6.1 xevion:v0.6.0 xevion:v0.5.5 xevion:v0.7.0 xevion:v0.7.1 xevion:v0.8.0 xevion:v0.9.0 xevion:v0.9.1 xevion:v0.9.2 xevion:v0.17.6 xevion:v0.10.1 xevion:v0.11.0 xevion:v0.12.0 xevion:v0.13.0 xevion:v0.14.0 xevion:v0.15.0 xevion:v0.16.0 xevion:v0.16.1 xevion:v0.17.0 xevion:v0.17.1 xevion:v0.17.2 xevion:v0.17.4 xevion:v0.17.3 xevion:v0.6.5 xevion:v0.10.0 xevion:v0.5.2 xevion:v0.5.1 xevion:v0.0.1 xevion:v0.1.0 xevion:v0.1.1 xevion:v0.1.2 xevion:v0.1.3 xevion:v0.1.4 xevion:v0.3.1 xevion:v0.2.1 xevion:v0.2.2 xevion:v0.5.3 xevion:v0.3.0 xevion:v0.5.4 xevion:v0.3.3 xevion:v0.3.4 xevion:v0.3.5 xevion:v0.4.0 xevion:v0.4.1 xevion:v0.4.2 xevion:v0.4.3 xevion:v0.4.4 xevion:v0.4.5 xevion:v0.4.6 xevion:v0.4.7 xevion:v0.5.0 xevion:v0.1.5 xevion:v0.3.2 xevion:v0.2.0
...
compare: xevion:v0.38.0
Branches Tags
xevion:dependabot/cargo/rust-minor-01c68be507 xevion:dependabot/cargo/rust-patches-eeb485b1b5 xevion:master xevion:server xevion:test
xevion:v0.81.1 xevion:v0.81.0 xevion:v0.80.3 xevion:v0.80.2 xevion:v0.80.1 xevion:v0.80.0 xevion:v0.79.2 xevion:v0.79.1 xevion:v0.79.0 xevion:v0.78.5 xevion:v0.78.4 xevion:v0.78.3 xevion:v0.78.2 xevion:v0.78.1 xevion:v0.78.0 xevion:v0.77.1 xevion:v0.77.0 xevion:v0.76.1 xevion:v0.76.0 xevion:v0.74.6 xevion:v0.74.5 xevion:v0.74.8 xevion:v0.74.7 xevion:v0.74.9 xevion:v0.74.11 xevion:v0.74.10 xevion:v0.75.1 xevion:v0.75.0 xevion:v0.52.1 xevion:v0.53.0 xevion:v0.53.1 xevion:v0.54.0 xevion:v0.55.0 xevion:v0.55.1 xevion:v0.55.2 xevion:v0.55.3 xevion:v0.56.0 xevion:v0.56.1 xevion:v0.56.2 xevion:v0.56.3 xevion:v0.56.4 xevion:v0.57.0 xevion:v0.57.1 xevion:v0.58.0 xevion:v0.59.0 xevion:v0.59.1 xevion:v0.60.0 xevion:v0.60.1 xevion:v0.60.2 xevion:v0.60.3 xevion:v0.61.0 xevion:v0.61.1 xevion:v0.62.0 xevion:v0.63.0 xevion:v0.64.0 xevion:v0.64.1 xevion:v0.65.0 xevion:v0.66.0 xevion:v0.67.0 xevion:v0.67.1 xevion:v0.68.0 xevion:v0.68.1 xevion:v0.70.0 xevion:v0.69.1 xevion:v0.69.0 xevion:v0.71.1 xevion:v0.71.0 xevion:v0.72.0 xevion:v0.73.0 xevion:v0.74.1 xevion:v0.74.0 xevion:v0.74.3 xevion:v0.74.2 xevion:v0.74.4 xevion:v0.36.0 xevion:v0.37.0 xevion:v0.37.1 xevion:v0.37.2 xevion:v0.38.0 xevion:v0.39.0 xevion:v0.39.1 xevion:v0.39.2 xevion:v0.39.3 xevion:v0.40.0 xevion:v0.40.1 xevion:v0.41.0 xevion:v0.41.1 xevion:v0.41.2 xevion:v0.41.3 xevion:v0.42.0 xevion:v0.42.1 xevion:v0.43.0 xevion:v0.44.0 xevion:v0.44.1 xevion:v0.44.2 xevion:v0.44.3 xevion:v0.44.4 xevion:v0.44.5 xevion:v0.45.0 xevion:v0.45.1 xevion:v0.46.0 xevion:v0.47.0 xevion:v0.47.1 xevion:v0.48.0 xevion:v0.48.1 xevion:v0.48.2 xevion:v0.48.3 xevion:v0.48.4 xevion:v0.48.5 xevion:v0.48.6 xevion:v0.48.7 xevion:v0.48.8 xevion:v0.49.0 xevion:v0.49.1 xevion:v0.50.0 xevion:v0.50.1 xevion:v0.51.0 xevion:v0.52.0 xevion:v0.34.10 xevion:v0.35.0 xevion:v0.23.10 xevion:v0.23.11 xevion:v0.23.12 xevion:v0.23.13 xevion:v0.23.14 xevion:v0.23.15 xevion:v0.23.16 xevion:v0.24.0 xevion:v0.24.1 xevion:v0.24.2 xevion:v0.24.3 xevion:v0.25.0 xevion:v0.34.9 xevion:v0.26.1 xevion:v0.26.2 xevion:v0.26.3 xevion:v0.26.4 xevion:v0.27.0 xevion:v0.27.1 xevion:v0.28.0 xevion:v0.28.1 xevion:v0.30.0 xevion:v0.29.0 xevion:v0.30.1 xevion:v0.30.2 xevion:v0.31.0 xevion:v0.31.1 xevion:v0.31.2 xevion:v0.31.3 xevion:v0.31.4 xevion:v0.31.5 xevion:v0.32.0 xevion:v0.32.1 xevion:v0.33.0 xevion:v0.34.0 xevion:v0.34.1 xevion:v0.34.2 xevion:v0.34.3 xevion:v0.34.4 xevion:v0.34.5 xevion:v0.34.6 xevion:v0.34.7 xevion:v0.34.8 xevion:v0.26.0 xevion:v0.23.8 xevion:v0.23.9 xevion:v0.17.9 xevion:v0.17.10 xevion:v0.17.11 xevion:v0.17.12 xevion:v0.17.13 xevion:v0.17.14 xevion:v0.23.7 xevion:v0.17.17 xevion:v0.17.16 xevion:v0.18.1 xevion:v0.18.0 xevion:v0.18.2 xevion:v0.18.3 xevion:v0.18.5 xevion:v0.18.4 xevion:v0.18.6 xevion:v0.18.7 xevion:v0.18.8 xevion:v0.18.9 xevion:v0.18.10 xevion:v0.18.11 xevion:v0.18.12 xevion:v0.18.13 xevion:v0.18.14 xevion:v0.18.15 xevion:v0.18.16 xevion:v0.19.0 xevion:v0.20.0 xevion:v0.21.0 xevion:v0.22.0 xevion:v0.22.1 xevion:v0.22.2 xevion:v0.22.3 xevion:v0.22.4 xevion:v0.23.0 xevion:v0.23.1 xevion:v0.23.2 xevion:v0.23.3 xevion:v0.23.4 xevion:v0.23.5 xevion:v0.23.6 xevion:v0.17.15 xevion:v0.17.7 xevion:v0.17.8 xevion:v0.6.9 xevion:v0.6.8 xevion:v0.6.7 xevion:v0.6.6 xevion:v0.17.5 xevion:v0.6.4 xevion:v0.6.3 xevion:v0.6.2 xevion:v0.6.18 xevion:v0.6.17 xevion:v0.6.16 xevion:v0.6.15 xevion:v0.6.14 xevion:v0.6.13 xevion:v0.6.12 xevion:v0.6.11 xevion:v0.6.10 xevion:v0.6.1 xevion:v0.6.0 xevion:v0.5.5 xevion:v0.7.0 xevion:v0.7.1 xevion:v0.8.0 xevion:v0.9.0 xevion:v0.9.1 xevion:v0.9.2 xevion:v0.17.6 xevion:v0.10.1 xevion:v0.11.0 xevion:v0.12.0 xevion:v0.13.0 xevion:v0.14.0 xevion:v0.15.0 xevion:v0.16.0 xevion:v0.16.1 xevion:v0.17.0 xevion:v0.17.1 xevion:v0.17.2 xevion:v0.17.4 xevion:v0.17.3 xevion:v0.6.5 xevion:v0.10.0 xevion:v0.5.2 xevion:v0.5.1 xevion:v0.0.1 xevion:v0.1.0 xevion:v0.1.1 xevion:v0.1.2 xevion:v0.1.3 xevion:v0.1.4 xevion:v0.3.1 xevion:v0.2.1 xevion:v0.2.2 xevion:v0.5.3 xevion:v0.3.0 xevion:v0.5.4 xevion:v0.3.3 xevion:v0.3.4 xevion:v0.3.5 xevion:v0.4.0 xevion:v0.4.1 xevion:v0.4.2 xevion:v0.4.3 xevion:v0.4.4 xevion:v0.4.5 xevion:v0.4.6 xevion:v0.4.7 xevion:v0.5.0 xevion:v0.1.5 xevion:v0.3.2 xevion:v0.2.0

10 Commits
v0.35.0 ... v0.38.0

Author SHA1 Message Date
Xevion
b270318640 feat: directional rendering, interactivity 2025-08-14 15:44:07 -05:00
Xevion
bc759f1ed4 refactor!: begin switching to bevy ECS, all tests broken, all systems broken 2025-08-14 15:06:56 -05:00
Xevion
2f1ff85d8f refactor: handle pausing within game, reduce input system allocations 2025-08-14 10:36:39 -05:00
Xevion
b7429cd9ec chore: solve tests/ clippy warnings 2025-08-14 09:46:10 -05:00
Xevion
12a63374a8 feat: avoid using spin sleep unless focused 2025-08-13 23:30:07 -05:00
Xevion
d80d7061e7 refactor: build decoupled input processing & add event queue system 2025-08-13 20:45:56 -05:00
Xevion
abdefe0af0 chore: add hidden note about why Coveralls.io is disappointing today 2025-08-13 19:52:58 -05:00
Xevion
4f76de7c9f feat: enable vsync & hardware acceleration 2025-08-13 19:49:02 -05:00
Xevion
db8cd6220a feat: cache dynamicly rendered map texture 2025-08-13 19:48:50 -05:00
Xevion
ced4e87d41 feat: embed atlas.json via phf instead of runtime parsing 2025-08-13 00:37:37 -05:00
35 changed files with 2710 additions and 1462 deletions
Expand all files Collapse all files

771
Cargo.lock generated
View File

File diff suppressed because it is too large Load Diff

7
Cargo.toml
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@@ -23,6 +23,8 @@ serde_json = "1.0.142"
smallvec = "1.15.1"
strum = "0.27.2"
strum_macros = "0.27.2"
phf = { version = "0.11", features = ["macros"] }
bevy_ecs = "0.16.1"
[profile.release]
lto = true
@@ -57,3 +59,8 @@ aarch64-apple-darwin = { triplet = "arm64-osx" }
[target.'cfg(target_os = "emscripten")'.dependencies]
libc = "0.2.175"
[build-dependencies]
serde = { version = "1.0", features = ["derive"] }
serde_json = "1.0"
phf = { version = "0.11", features = ["macros"] }

2
README.md
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@@ -1,6 +1,6 @@
# Pac-Man
[![Tests Status][badge-test]][test] [![Build Status][badge-build]][build] [![Code Coverage][badge-coverage]][coverage] [![Online Demo][badge-online-demo]][demo] [![Last Commit][badge-last-commit]][commits]
[![Tests Status][badge-test]][test] [![Build Status][badge-build]][build] [![If you're seeing this, Coveralls.io is broken again and it's not my fault.][badge-coverage]][coverage] [![Online Demo][badge-online-demo]][demo] [![Last Commit][badge-last-commit]][commits]
[badge-test]: https://github.com/Xevion/Pac-Man/actions/workflows/tests.yaml/badge.svg
[badge-build]: https://github.com/Xevion/Pac-Man/actions/workflows/build.yaml/badge.svg

50
build.rs Normal file
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@@ -0,0 +1,50 @@
use std::collections::HashMap;
use std::env;
use std::fs::File;
use std::io::{BufWriter, Write};
use std::path::Path;
use serde::Deserialize;
#[derive(Debug, Deserialize)]
struct AtlasMapper {
frames: HashMap<String, MapperFrame>,
}
#[derive(Copy, Clone, Debug, Deserialize)]
struct MapperFrame {
x: u16,
y: u16,
width: u16,
height: u16,
}
fn main() {
let path = Path::new(&env::var("OUT_DIR").unwrap()).join("atlas_data.rs");
let mut file = BufWriter::new(File::create(&path).unwrap());
let atlas_json = include_str!("./assets/game/atlas.json");
let atlas_mapper: AtlasMapper = serde_json::from_str(atlas_json).unwrap();
writeln!(&mut file, "use phf::phf_map;").unwrap();
writeln!(&mut file, "use crate::texture::sprite::MapperFrame;").unwrap();
writeln!(
&mut file,
"pub static ATLAS_FRAMES: phf::Map<&'static str, MapperFrame> = phf_map! {{"
)
.unwrap();
for (name, frame) in atlas_mapper.frames {
writeln!(
&mut file,
" \"{}\" => MapperFrame {{ x: {}, y: {}, width: {}, height: {} }},",
name, frame.x, frame.y, frame.width, frame.height
)
.unwrap();
}
writeln!(&mut file, "}};").unwrap();
println!("cargo:rerun-if-changed=assets/game/atlas.json");
}

140
src/app.rs
View File

@@ -1,13 +1,11 @@
use std::time::{Duration, Instant};
use glam::Vec2;
use sdl2::event::{Event, WindowEvent};
use sdl2::keyboard::Keycode;
use sdl2::render::{Canvas, ScaleMode, Texture, TextureCreator};
use sdl2::ttf::Sdl2TtfContext;
use sdl2::video::{Window, WindowContext};
use sdl2::{AudioSubsystem, EventPump, Sdl, VideoSubsystem};
use tracing::{error, event};
use tracing::{error, warn};
use crate::error::{GameError, GameResult};
@@ -16,12 +14,9 @@ use crate::game::Game;
use crate::platform::get_platform;
pub struct App {
game: Game,
canvas: Canvas<Window>,
event_pump: &'static mut EventPump,
backbuffer: Texture<'static>,
paused: bool,
pub game: Game,
last_tick: Instant,
focused: bool,
cursor_pos: Vec2,
}
@@ -51,33 +46,33 @@ impl App {
.build()
.map_err(|e| GameError::Sdl(e.to_string()))?;
let mut canvas = window.into_canvas().build().map_err(|e| GameError::Sdl(e.to_string()))?;
let mut canvas = Box::leak(Box::new(
window
.into_canvas()
.accelerated()
.present_vsync()
.build()
.map_err(|e| GameError::Sdl(e.to_string()))?,
));
canvas
.set_logical_size(CANVAS_SIZE.x, CANVAS_SIZE.y)
.map_err(|e| GameError::Sdl(e.to_string()))?;
let texture_creator: &'static TextureCreator<WindowContext> = Box::leak(Box::new(canvas.texture_creator()));
let texture_creator: &'static mut TextureCreator<WindowContext> = Box::leak(Box::new(canvas.texture_creator()));
let mut game = Game::new(texture_creator)?;
let game = Game::new(canvas, texture_creator, event_pump)?;
// game.audio.set_mute(cfg!(debug_assertions));
let mut backbuffer = texture_creator
.create_texture_target(None, CANVAS_SIZE.x, CANVAS_SIZE.y)
.map_err(|e| GameError::Sdl(e.to_string()))?;
backbuffer.set_scale_mode(ScaleMode::Nearest);
// Initial draw
game.draw(&mut canvas, &mut backbuffer)
.map_err(|e| GameError::Sdl(e.to_string()))?;
game.present_backbuffer(&mut canvas, &backbuffer, glam::Vec2::ZERO)
.map_err(|e| GameError::Sdl(e.to_string()))?;
// game.draw(&mut canvas, &mut backbuffer)
// .map_err(|e| GameError::Sdl(e.to_string()))?;
// game.present_backbuffer(&mut canvas, &backbuffer, glam::Vec2::ZERO)
// .map_err(|e| GameError::Sdl(e.to_string()))?;
Ok(Self {
Ok(App {
game,
canvas,
event_pump,
backbuffer,
paused: false,
focused: true,
last_tick: Instant::now(),
cursor_pos: Vec2::ZERO,
})
@@ -87,78 +82,51 @@ impl App {
{
let start = Instant::now();
for event in self.event_pump.poll_iter() {
match event {
Event::Window { win_event, .. } => match win_event {
WindowEvent::Hidden => {
event!(tracing::Level::DEBUG, "Window hidden");
}
WindowEvent::Shown => {
event!(tracing::Level::DEBUG, "Window shown");
}
_ => {}
},
// It doesn't really make sense to have this available in the browser
#[cfg(not(target_os = "emscripten"))]
Event::Quit { .. }
| Event::KeyDown {
keycode: Some(Keycode::Escape) | Some(Keycode::Q),
..
} => {
event!(tracing::Level::INFO, "Exit requested. Exiting...");
return false;
}
Event::KeyDown {
keycode: Some(Keycode::P),
..
} => {
self.paused = !self.paused;
event!(tracing::Level::INFO, "{}", if self.paused { "Paused" } else { "Unpaused" });
}
Event::KeyDown {
keycode: Some(Keycode::Space),
..
} => {
self.game.toggle_debug_mode();
}
Event::KeyDown { keycode: Some(key), .. } => {
self.game.keyboard_event(key);
}
Event::MouseMotion { x, y, .. } => {
// Convert window coordinates to logical coordinates
self.cursor_pos = Vec2::new(x as f32, y as f32);
}
_ => {}
}
}
// for event in self
// .game
// .world
// .get_non_send_resource_mut::<&'static mut EventPump>()
// .unwrap()
// .poll_iter()
// {
// match event {
// Event::Window { win_event, .. } => match win_event {
// WindowEvent::FocusGained => {
// self.focused = true;
// }
// WindowEvent::FocusLost => {
// self.focused = false;
// }
// _ => {}
// },
// Event::MouseMotion { x, y, .. } => {
// // Convert window coordinates to logical coordinates
// self.cursor_pos = Vec2::new(x as f32, y as f32);
// }
// _ => {}
// }
// }
let dt = self.last_tick.elapsed().as_secs_f32();
self.last_tick = Instant::now();
if !self.paused {
self.game.tick(dt);
if let Err(e) = self.game.draw(&mut self.canvas, &mut self.backbuffer) {
error!("Failed to draw game: {}", e);
}
if let Err(e) = self
.game
.present_backbuffer(&mut self.canvas, &self.backbuffer, self.cursor_pos)
{
error!("Failed to present backbuffer: {}", e);
}
let exit = self.game.tick(dt);
if exit {
return false;
}
// if let Err(e) = self.game.draw(&mut self.canvas, &mut self.backbuffer) {
// error!("Failed to draw game: {}", e);
// }
if start.elapsed() < LOOP_TIME {
let time = LOOP_TIME.saturating_sub(start.elapsed());
if time != Duration::ZERO {
get_platform().sleep(time);
get_platform().sleep(time, self.focused);
}
} else {
event!(
tracing::Level::WARN,
"Game loop behind schedule by: {:?}",
start.elapsed() - LOOP_TIME
);
warn!("Game loop behind schedule by: {:?}", start.elapsed() - LOOP_TIME);
}
true

4
src/asset.rs
View File

@@ -12,8 +12,6 @@ pub enum Asset {
Wav3,
Wav4,
Atlas,
AtlasJson,
// Add more as needed
}
impl Asset {
@@ -26,7 +24,6 @@ impl Asset {
Wav3 => "sound/waka/3.ogg",
Wav4 => "sound/waka/4.ogg",
Atlas => "atlas.png",
AtlasJson => "atlas.json",
}
}
}
@@ -36,6 +33,7 @@ mod imp {
use crate::error::AssetError;
use crate::platform::get_platform;
/// Returns the raw bytes of the given asset.
pub fn get_asset_bytes(asset: Asset) -> Result<Cow<'static, [u8]>, AssetError> {
get_platform().get_asset_bytes(asset)
}

44
src/ecs/interact.rs Normal file
View File

@@ -0,0 +1,44 @@
use bevy_ecs::{
event::{EventReader, EventWriter},
query::With,
system::{Query, ResMut},
};
use crate::{
ecs::{GlobalState, PlayerControlled, Velocity},
error::GameError,
game::events::GameEvent,
input::commands::GameCommand,
};
// Handles
pub fn interact_system(
mut events: EventReader<GameEvent>,
mut state: ResMut<GlobalState>,
mut players: Query<(&PlayerControlled, &mut Velocity)>,
mut errors: EventWriter<GameError>,
) {
// Get the player's velocity (handling to ensure there is only one player)
let mut velocity = match players.single_mut() {
Ok((_, velocity)) => velocity,
Err(e) => {
errors.write(GameError::InvalidState(format!("Player not found: {}", e)).into());
return;
}
};
// Handle events
for event in events.read() {
match event {
GameEvent::Command(command) => match command {
GameCommand::MovePlayer(direction) => {
velocity.direction = *direction;
}
GameCommand::Exit => {
state.exit = true;
}
_ => {}
},
}
}
}

149
src/ecs/mod.rs Normal file
View File

@@ -0,0 +1,149 @@
//! The Entity-Component-System (ECS) module.
//!
//! This module contains all the ECS-related logic, including components, systems,
//! and resources.
use bevy_ecs::{bundle::Bundle, component::Component, resource::Resource};
use glam::Vec2;
use crate::{
entity::{direction::Direction, graph::Graph, traversal},
error::{EntityError, GameResult},
texture::{
animated::AnimatedTexture,
directional::DirectionalAnimatedTexture,
sprite::{AtlasTile, Sprite},
},
};
/// A tag component for entities that are controlled by the player.
#[derive(Default, Component)]
pub struct PlayerControlled;
/// A component for entities that have a sprite, with a layer for ordering.
///
/// This is intended to be modified by other entities allowing animation.
#[derive(Component)]
pub struct Renderable {
pub sprite: AtlasTile,
pub layer: u8,
}
/// A component for entities that have a directional animated texture.
#[derive(Component)]
pub struct DirectionalAnimated {
pub textures: [Option<AnimatedTexture>; 4],
pub stopped_textures: [Option<AnimatedTexture>; 4],
}
/// A unique identifier for a node, represented by its index in the graph's storage.
pub type NodeId = usize;
/// Represents the current position of an entity traversing the graph.
///
/// This enum allows for precise tracking of whether an entity is exactly at a node
/// or moving along an edge between two nodes.
#[derive(Component, Debug, Copy, Clone, PartialEq)]
pub enum Position {
/// The traverser is located exactly at a node.
AtNode(NodeId),
/// The traverser is on an edge between two nodes.
BetweenNodes {
from: NodeId,
to: NodeId,
/// The floating-point distance traversed along the edge from the `from` node.
traversed: f32,
},
}
impl Position {
/// Calculates the current pixel position in the game world.
///
/// Converts the graph position to screen coordinates, accounting for
/// the board offset and centering the sprite.
pub fn get_pixel_pos(&self, graph: &Graph) -> GameResult<Vec2> {
let pos = match self {
Position::AtNode(node_id) => {
let node = graph.get_node(*node_id).ok_or(EntityError::NodeNotFound(*node_id))?;
node.position
}
Position::BetweenNodes { from, to, traversed } => {
let from_node = graph.get_node(*from).ok_or(EntityError::NodeNotFound(*from))?;
let to_node = graph.get_node(*to).ok_or(EntityError::NodeNotFound(*to))?;
let edge = graph
.find_edge(*from, *to)
.ok_or(EntityError::EdgeNotFound { from: *from, to: *to })?;
from_node.position + (to_node.position - from_node.position) * (traversed / edge.distance)
}
};
Ok(Vec2::new(
pos.x + crate::constants::BOARD_PIXEL_OFFSET.x as f32,
pos.y + crate::constants::BOARD_PIXEL_OFFSET.y as f32,
))
}
}
impl Default for Position {
fn default() -> Self {
Position::AtNode(0)
}
}
#[allow(dead_code)]
impl Position {
/// Returns `true` if the position is exactly at a node.
pub fn is_at_node(&self) -> bool {
matches!(self, Position::AtNode(_))
}
/// Returns the `NodeId` of the current or most recently departed node.
#[allow(clippy::wrong_self_convention)]
pub fn from_node_id(&self) -> NodeId {
match self {
Position::AtNode(id) => *id,
Position::BetweenNodes { from, .. } => *from,
}
}
/// Returns the `NodeId` of the destination node, if currently on an edge.
#[allow(clippy::wrong_self_convention)]
pub fn to_node_id(&self) -> Option<NodeId> {
match self {
Position::AtNode(_) => None,
Position::BetweenNodes { to, .. } => Some(*to),
}
}
/// Returns `true` if the traverser is stopped at a node.
pub fn is_stopped(&self) -> bool {
matches!(self, Position::AtNode(_))
}
}
/// A component for entities that have a velocity, with a direction and speed.
#[derive(Default, Component)]
pub struct Velocity {
pub direction: Direction,
pub speed: Option<f32>,
}
#[derive(Bundle)]
pub struct PlayerBundle {
pub player: PlayerControlled,
pub position: Position,
pub velocity: Velocity,
pub sprite: Renderable,
pub directional_animated: DirectionalAnimated,
}
#[derive(Resource)]
pub struct GlobalState {
pub exit: bool,
}
#[derive(Resource)]
pub struct DeltaTime(pub f32);
pub mod interact;
pub mod render;

95
src/ecs/render.rs Normal file
View File

@@ -0,0 +1,95 @@
use crate::ecs::{DeltaTime, DirectionalAnimated, Position, Renderable, Velocity};
use crate::error::{EntityError, GameError, TextureError};
use crate::map::builder::Map;
use crate::texture::sprite::SpriteAtlas;
use bevy_ecs::entity::Entity;
use bevy_ecs::event::EventWriter;
use bevy_ecs::system::{NonSendMut, Query, Res};
use sdl2::render::{Canvas, Texture};
use sdl2::video::Window;
/// Updates the directional animated texture of an entity.
pub fn directional_render_system(
dt: Res<DeltaTime>,
mut renderables: Query<(&Velocity, &mut DirectionalAnimated, &mut Renderable)>,
mut errors: EventWriter<GameError>,
) {
for (velocity, mut texture, mut renderable) in renderables.iter_mut() {
let texture = if velocity.speed.is_none() {
texture.stopped_textures[velocity.direction.as_usize()].as_mut()
} else {
texture.textures[velocity.direction.as_usize()].as_mut()
};
if let Some(texture) = texture {
texture.tick(dt.0);
renderable.sprite = *texture.current_tile();
} else {
errors.write(TextureError::RenderFailed(format!("Entity has no texture")).into());
continue;
}
}
}
pub struct MapTextureResource(pub Texture<'static>);
pub struct BackbufferResource(pub Texture<'static>);
pub fn render_system(
mut canvas: NonSendMut<&mut Canvas<Window>>,
map_texture: NonSendMut<MapTextureResource>,
mut backbuffer: NonSendMut<BackbufferResource>,
mut atlas: NonSendMut<SpriteAtlas>,
map: Res<Map>,
mut renderables: Query<(Entity, &mut Renderable, &Position)>,
mut errors: EventWriter<GameError>,
) {
// Clear the main canvas first
canvas.set_draw_color(sdl2::pixels::Color::BLACK);
canvas.clear();
// Render to backbuffer
canvas
.with_texture_canvas(&mut backbuffer.0, |backbuffer_canvas| {
// Clear the backbuffer
backbuffer_canvas.set_draw_color(sdl2::pixels::Color::BLACK);
backbuffer_canvas.clear();
// Copy the pre-rendered map texture to the backbuffer
backbuffer_canvas
.copy(&map_texture.0, None, None)
.err()
.map(|e| errors.write(TextureError::RenderFailed(e.to_string()).into()));
// Render all entities to the backbuffer
for (_, mut renderable, position) in renderables.iter_mut() {
let pos = position.get_pixel_pos(&map.graph);
match pos {
Ok(pos) => {
let dest = crate::helpers::centered_with_size(
glam::IVec2::new(pos.x as i32, pos.y as i32),
glam::UVec2::new(renderable.sprite.size.x as u32, renderable.sprite.size.y as u32),
);
renderable
.sprite
.render(backbuffer_canvas, &mut atlas, dest)
.err()
.map(|e| errors.write(TextureError::RenderFailed(e.to_string()).into()));
}
Err(e) => {
errors.write(e.into());
}
}
}
})
.err()
.map(|e| errors.write(TextureError::RenderFailed(e.to_string()).into()));
// Copy backbuffer to main canvas and present
canvas
.copy(&backbuffer.0, None, None)
.err()
.map(|e| errors.write(TextureError::RenderFailed(e.to_string()).into()));
canvas.present();
}

214
src/entity/collision.rs
View File

@@ -1,128 +1,128 @@
use smallvec::SmallVec;
use std::collections::HashMap;
// use smallvec::SmallVec;
// use std::collections::HashMap;
use crate::entity::{graph::NodeId, traversal::Position};
// use crate::entity::{graph::NodeId, traversal::Position};
/// Trait for entities that can participate in collision detection.
pub trait Collidable {
/// Returns the current position of this entity.
fn position(&self) -> Position;
// /// Trait for entities that can participate in collision detection.
// pub trait Collidable {
// /// Returns the current position of this entity.
// fn position(&self) -> Position;
/// Checks if this entity is colliding with another entity.
#[allow(dead_code)]
fn is_colliding_with(&self, other: &dyn Collidable) -> bool {
positions_overlap(&self.position(), &other.position())
}
}
// /// Checks if this entity is colliding with another entity.
// #[allow(dead_code)]
// fn is_colliding_with(&self, other: &dyn Collidable) -> bool {
// positions_overlap(&self.position(), &other.position())
// }
// }
/// System for tracking entities by their positions for efficient collision detection.
#[derive(Default)]
pub struct CollisionSystem {
/// Maps node IDs to lists of entity IDs that are at that node
node_entities: HashMap<NodeId, Vec<EntityId>>,
/// Maps entity IDs to their current positions
entity_positions: HashMap<EntityId, Position>,
/// Next available entity ID
next_id: EntityId,
}
// /// System for tracking entities by their positions for efficient collision detection.
// #[derive(Default)]
// pub struct CollisionSystem {
// /// Maps node IDs to lists of entity IDs that are at that node
// node_entities: HashMap<NodeId, Vec<EntityId>>,
// /// Maps entity IDs to their current positions
// entity_positions: HashMap<EntityId, Position>,
// /// Next available entity ID
// next_id: EntityId,
// }
/// Unique identifier for an entity in the collision system
pub type EntityId = u32;
// /// Unique identifier for an entity in the collision system
// pub type EntityId = u32;
impl CollisionSystem {
/// Registers an entity with the collision system and returns its ID
pub fn register_entity(&mut self, position: Position) -> EntityId {
let id = self.next_id;
self.next_id += 1;
// impl CollisionSystem {
// /// Registers an entity with the collision system and returns its ID
// pub fn register_entity(&mut self, position: Position) -> EntityId {
// let id = self.next_id;
// self.next_id += 1;
self.entity_positions.insert(id, position);
self.update_node_entities(id, position);
// self.entity_positions.insert(id, position);
// self.update_node_entities(id, position);
id
}
// id
// }
/// Updates an entity's position
pub fn update_position(&mut self, entity_id: EntityId, new_position: Position) {
if let Some(old_position) = self.entity_positions.get(&entity_id) {
// Remove from old nodes
self.remove_from_nodes(entity_id, *old_position);
}
// /// Updates an entity's position
// pub fn update_position(&mut self, entity_id: EntityId, new_position: Position) {
// if let Some(old_position) = self.entity_positions.get(&entity_id) {
// // Remove from old nodes
// self.remove_from_nodes(entity_id, *old_position);
// }
// Update position and add to new nodes
self.entity_positions.insert(entity_id, new_position);
self.update_node_entities(entity_id, new_position);
}
// // Update position and add to new nodes
// self.entity_positions.insert(entity_id, new_position);
// self.update_node_entities(entity_id, new_position);
// }
/// Removes an entity from the collision system
#[allow(dead_code)]
pub fn remove_entity(&mut self, entity_id: EntityId) {
if let Some(position) = self.entity_positions.remove(&entity_id) {
self.remove_from_nodes(entity_id, position);
}
}
// /// Removes an entity from the collision system
// #[allow(dead_code)]
// pub fn remove_entity(&mut self, entity_id: EntityId) {
// if let Some(position) = self.entity_positions.remove(&entity_id) {
// self.remove_from_nodes(entity_id, position);
// }
// }
/// Gets all entity IDs at a specific node
pub fn entities_at_node(&self, node: NodeId) -> &[EntityId] {
self.node_entities.get(&node).map(|v| v.as_slice()).unwrap_or(&[])
}
// /// Gets all entity IDs at a specific node
// pub fn entities_at_node(&self, node: NodeId) -> &[EntityId] {
// self.node_entities.get(&node).map(|v| v.as_slice()).unwrap_or(&[])
// }
/// Gets all entity IDs that could collide with an entity at the given position
pub fn potential_collisions(&self, position: &Position) -> Vec<EntityId> {
let mut collisions = Vec::new();
let nodes = get_nodes(position);
// /// Gets all entity IDs that could collide with an entity at the given position
// pub fn potential_collisions(&self, position: &Position) -> Vec<EntityId> {
// let mut collisions = Vec::new();
// let nodes = get_nodes(position);
for node in nodes {
collisions.extend(self.entities_at_node(node));
}
// for node in nodes {
// collisions.extend(self.entities_at_node(node));
// }
// Remove duplicates
collisions.sort_unstable();
collisions.dedup();
collisions
}
// // Remove duplicates
// collisions.sort_unstable();
// collisions.dedup();
// collisions
// }
/// Updates the node_entities map when an entity's position changes
fn update_node_entities(&mut self, entity_id: EntityId, position: Position) {
let nodes = get_nodes(&position);
for node in nodes {
self.node_entities.entry(node).or_default().push(entity_id);
}
}
// /// Updates the node_entities map when an entity's position changes
// fn update_node_entities(&mut self, entity_id: EntityId, position: Position) {
// let nodes = get_nodes(&position);
// for node in nodes {
// self.node_entities.entry(node).or_default().push(entity_id);
// }
// }
/// Removes an entity from all nodes it was previously at
fn remove_from_nodes(&mut self, entity_id: EntityId, position: Position) {
let nodes = get_nodes(&position);
for node in nodes {
if let Some(entities) = self.node_entities.get_mut(&node) {
entities.retain(|&id| id != entity_id);
if entities.is_empty() {
self.node_entities.remove(&node);
}
}
}
}
}
// /// Removes an entity from all nodes it was previously at
// fn remove_from_nodes(&mut self, entity_id: EntityId, position: Position) {
// let nodes = get_nodes(&position);
// for node in nodes {
// if let Some(entities) = self.node_entities.get_mut(&node) {
// entities.retain(|&id| id != entity_id);
// if entities.is_empty() {
// self.node_entities.remove(&node);
// }
// }
// }
// }
// }
/// Checks if two positions overlap (entities are at the same location).
fn positions_overlap(a: &Position, b: &Position) -> bool {
let a_nodes = get_nodes(a);
let b_nodes = get_nodes(b);
// /// Checks if two positions overlap (entities are at the same location).
// fn positions_overlap(a: &Position, b: &Position) -> bool {
// let a_nodes = get_nodes(a);
// let b_nodes = get_nodes(b);
// Check if any nodes overlap
a_nodes.iter().any(|a_node| b_nodes.contains(a_node))
// // Check if any nodes overlap
// a_nodes.iter().any(|a_node| b_nodes.contains(a_node))
// TODO: More complex overlap detection, the above is a simple check, but it could become an early filter for more precise calculations later
}
// // TODO: More complex overlap detection, the above is a simple check, but it could become an early filter for more precise calculations later
// }
/// Gets all nodes that an entity is currently at or between.
fn get_nodes(pos: &Position) -> SmallVec<[NodeId; 2]> {
let mut nodes = SmallVec::new();
match pos {
Position::AtNode(node) => nodes.push(*node),
Position::BetweenNodes { from, to, .. } => {
nodes.push(*from);
nodes.push(*to);
}
}
nodes
}
// /// Gets all nodes that an entity is currently at or between.
// fn get_nodes(pos: &Position) -> SmallVec<[NodeId; 2]> {
// let mut nodes = SmallVec::new();
// match pos {
// Position::AtNode(node) => nodes.push(*node),
// Position::BetweenNodes { from, to, .. } => {
// nodes.push(*from);
// nodes.push(*to);
// }
// }
// nodes
// }

4
src/entity/direction.rs
View File

@@ -1,11 +1,13 @@
use glam::IVec2;
/// The four cardinal directions.
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash, Default)]
#[repr(usize)]
pub enum Direction {
Up,
Down,
Left,
#[default]
Right,
}

448
src/entity/ghost.rs
View File

@@ -1,254 +1,254 @@
//! Ghost entity implementation.
//!
//! This module contains the ghost character logic, including movement,
//! animation, and rendering. Ghosts move through the game graph using
//! a traverser and display directional animated textures.
// //! Ghost entity implementation.
// //!
// //! This module contains the ghost character logic, including movement,
// //! animation, and rendering. Ghosts move through the game graph using
// //! a traverser and display directional animated textures.
use pathfinding::prelude::dijkstra;
use rand::prelude::*;
use smallvec::SmallVec;
use tracing::error;
// use pathfinding::prelude::dijkstra;
// use rand::prelude::*;
// use smallvec::SmallVec;
// use tracing::error;
use crate::entity::{
collision::Collidable,
direction::Direction,
graph::{Edge, EdgePermissions, Graph, NodeId},
r#trait::Entity,
traversal::Traverser,
};
use crate::texture::animated::AnimatedTexture;
use crate::texture::directional::DirectionalAnimatedTexture;
use crate::texture::sprite::SpriteAtlas;
// use crate::entity::{
// collision::Collidable,
// direction::Direction,
// graph::{Edge, EdgePermissions, Graph, NodeId},
// r#trait::Entity,
// traversal::Traverser,
// };
// use crate::texture::animated::AnimatedTexture;
// use crate::texture::directional::DirectionalAnimatedTexture;
// use crate::texture::sprite::SpriteAtlas;
use crate::error::{EntityError, GameError, GameResult, TextureError};
// use crate::error::{EntityError, GameError, GameResult, TextureError};
/// Determines if a ghost can traverse a given edge.
///
/// Ghosts can move through edges that allow all entities or ghost-only edges.
fn can_ghost_traverse(edge: Edge) -> bool {
matches!(edge.permissions, EdgePermissions::All | EdgePermissions::GhostsOnly)
}
// /// Determines if a ghost can traverse a given edge.
// ///
// /// Ghosts can move through edges that allow all entities or ghost-only edges.
// fn can_ghost_traverse(edge: Edge) -> bool {
// matches!(edge.permissions, EdgePermissions::All | EdgePermissions::GhostsOnly)
// }
/// The four classic ghost types.
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub enum GhostType {
Blinky,
Pinky,
Inky,
Clyde,
}
// /// The four classic ghost types.
// #[derive(Debug, Clone, Copy, PartialEq, Eq)]
// pub enum GhostType {
// Blinky,
// Pinky,
// Inky,
// Clyde,
// }
impl GhostType {
/// Returns the ghost type name for atlas lookups.
pub fn as_str(self) -> &'static str {
match self {
GhostType::Blinky => "blinky",
GhostType::Pinky => "pinky",
GhostType::Inky => "inky",
GhostType::Clyde => "clyde",
}
}
// impl GhostType {
// /// Returns the ghost type name for atlas lookups.
// pub fn as_str(self) -> &'static str {
// match self {
// GhostType::Blinky => "blinky",
// GhostType::Pinky => "pinky",
// GhostType::Inky => "inky",
// GhostType::Clyde => "clyde",
// }
// }
/// Returns the base movement speed for this ghost type.
pub fn base_speed(self) -> f32 {
match self {
GhostType::Blinky => 1.0,
GhostType::Pinky => 0.95,
GhostType::Inky => 0.9,
GhostType::Clyde => 0.85,
}
}
}
// /// Returns the base movement speed for this ghost type.
// pub fn base_speed(self) -> f32 {
// match self {
// GhostType::Blinky => 1.0,
// GhostType::Pinky => 0.95,
// GhostType::Inky => 0.9,
// GhostType::Clyde => 0.85,
// }
// }
// }
/// A ghost entity that roams the game world.
///
/// Ghosts move through the game world using a graph-based navigation system
/// and display directional animated sprites. They randomly choose directions
/// at each intersection.
pub struct Ghost {
/// Handles movement through the game graph
pub traverser: Traverser,
/// The type of ghost (affects appearance and speed)
pub ghost_type: GhostType,
/// Manages directional animated textures for different movement states
texture: DirectionalAnimatedTexture,
/// Current movement speed
speed: f32,
}
// /// A ghost entity that roams the game world.
// ///
// /// Ghosts move through the game world using a graph-based navigation system
// /// and display directional animated sprites. They randomly choose directions
// /// at each intersection.
// pub struct Ghost {
// /// Handles movement through the game graph
// pub traverser: Traverser,
// /// The type of ghost (affects appearance and speed)
// pub ghost_type: GhostType,
// /// Manages directional animated textures for different movement states
// texture: DirectionalAnimatedTexture,
// /// Current movement speed
// speed: f32,
// }
impl Entity for Ghost {
fn traverser(&self) -> &Traverser {
&self.traverser
}
// impl Entity for Ghost {
// fn traverser(&self) -> &Traverser {
// &self.traverser
// }
fn traverser_mut(&mut self) -> &mut Traverser {
&mut self.traverser
}
// fn traverser_mut(&mut self) -> &mut Traverser {
// &mut self.traverser
// }
fn texture(&self) -> &DirectionalAnimatedTexture {
&self.texture
}
// fn texture(&self) -> &DirectionalAnimatedTexture {
// &self.texture
// }
fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture {
&mut self.texture
}
// fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture {
// &mut self.texture
// }
fn speed(&self) -> f32 {
self.speed
}
// fn speed(&self) -> f32 {
// self.speed
// }
fn can_traverse(&self, edge: Edge) -> bool {
can_ghost_traverse(edge)
}
// fn can_traverse(&self, edge: Edge) -> bool {
// can_ghost_traverse(edge)
// }
fn tick(&mut self, dt: f32, graph: &Graph) {
// Choose random direction when at a node
if self.traverser.position.is_at_node() {
self.choose_random_direction(graph);
}
// fn tick(&mut self, dt: f32, graph: &Graph) {
// // Choose random direction when at a node
// if self.traverser.position.is_at_node() {
// self.choose_random_direction(graph);
// }
if let Err(e) = self.traverser.advance(graph, dt * 60.0 * self.speed, &can_ghost_traverse) {
error!("Ghost movement error: {}", e);
}
self.texture.tick(dt);
}
}
// if let Err(e) = self.traverser.advance(graph, dt * 60.0 * self.speed, &can_ghost_traverse) {
// error!("Ghost movement error: {}", e);
// }
// self.texture.tick(dt);
// }
// }
impl Ghost {
/// Creates a new ghost instance at the specified starting node.
///
/// Sets up animated textures for all four directions with moving and stopped states.
/// The moving animation cycles through two sprite variants.
pub fn new(graph: &Graph, start_node: NodeId, ghost_type: GhostType, atlas: &SpriteAtlas) -> GameResult<Self> {
let mut textures = [None, None, None, None];
let mut stopped_textures = [None, None, None, None];
// impl Ghost {
// /// Creates a new ghost instance at the specified starting node.
// ///
// /// Sets up animated textures for all four directions with moving and stopped states.
// /// The moving animation cycles through two sprite variants.
// pub fn new(graph: &Graph, start_node: NodeId, ghost_type: GhostType, atlas: &SpriteAtlas) -> GameResult<Self> {
// let mut textures = [None, None, None, None];
// let mut stopped_textures = [None, None, None, None];
for direction in Direction::DIRECTIONS {
let moving_prefix = match direction {
Direction::Up => "up",
Direction::Down => "down",
Direction::Left => "left",
Direction::Right => "right",
};
let moving_tiles = vec![
SpriteAtlas::get_tile(atlas, &format!("ghost/{}/{}_{}.png", ghost_type.as_str(), moving_prefix, "a"))
.ok_or_else(|| {
GameError::Texture(TextureError::AtlasTileNotFound(format!(
"ghost/{}/{}_{}.png",
ghost_type.as_str(),
moving_prefix,
"a"
)))
})?,
SpriteAtlas::get_tile(atlas, &format!("ghost/{}/{}_{}.png", ghost_type.as_str(), moving_prefix, "b"))
.ok_or_else(|| {
GameError::Texture(TextureError::AtlasTileNotFound(format!(
"ghost/{}/{}_{}.png",
ghost_type.as_str(),
moving_prefix,
"b"
)))
})?,
];
// for direction in Direction::DIRECTIONS {
// let moving_prefix = match direction {
// Direction::Up => "up",
// Direction::Down => "down",
// Direction::Left => "left",
// Direction::Right => "right",
// };
// let moving_tiles = vec![
// SpriteAtlas::get_tile(atlas, &format!("ghost/{}/{}_{}.png", ghost_type.as_str(), moving_prefix, "a"))
// .ok_or_else(|| {
// GameError::Texture(TextureError::AtlasTileNotFound(format!(
// "ghost/{}/{}_{}.png",
// ghost_type.as_str(),
// moving_prefix,
// "a"
// )))
// })?,
// SpriteAtlas::get_tile(atlas, &format!("ghost/{}/{}_{}.png", ghost_type.as_str(), moving_prefix, "b"))
// .ok_or_else(|| {
// GameError::Texture(TextureError::AtlasTileNotFound(format!(
// "ghost/{}/{}_{}.png",
// ghost_type.as_str(),
// moving_prefix,
// "b"
// )))
// })?,
// ];
let stopped_tiles =
vec![
SpriteAtlas::get_tile(atlas, &format!("ghost/{}/{}_{}.png", ghost_type.as_str(), moving_prefix, "a"))
.ok_or_else(|| {
GameError::Texture(TextureError::AtlasTileNotFound(format!(
"ghost/{}/{}_{}.png",
ghost_type.as_str(),
moving_prefix,
"a"
)))
})?,
];
// let stopped_tiles =
// vec![
// SpriteAtlas::get_tile(atlas, &format!("ghost/{}/{}_{}.png", ghost_type.as_str(), moving_prefix, "a"))
// .ok_or_else(|| {
// GameError::Texture(TextureError::AtlasTileNotFound(format!(
// "ghost/{}/{}_{}.png",
// ghost_type.as_str(),
// moving_prefix,
// "a"
// )))
// })?,
// ];
textures[direction.as_usize()] = Some(AnimatedTexture::new(moving_tiles, 0.2)?);
stopped_textures[direction.as_usize()] = Some(AnimatedTexture::new(stopped_tiles, 0.1)?);
}
// textures[direction.as_usize()] = Some(AnimatedTexture::new(moving_tiles, 0.2)?);
// stopped_textures[direction.as_usize()] = Some(AnimatedTexture::new(stopped_tiles, 0.1)?);
// }
Ok(Self {
traverser: Traverser::new(graph, start_node, Direction::Left, &can_ghost_traverse),
ghost_type,
texture: DirectionalAnimatedTexture::new(textures, stopped_textures),
speed: ghost_type.base_speed(),
})
}
// Ok(Self {
// traverser: Traverser::new(graph, start_node, Direction::Left, &can_ghost_traverse),
// ghost_type,
// texture: DirectionalAnimatedTexture::new(textures, stopped_textures),
// speed: ghost_type.base_speed(),
// })
// }
/// Chooses a random available direction at the current intersection.
fn choose_random_direction(&mut self, graph: &Graph) {
let current_node = self.traverser.position.from_node_id();
let intersection = &graph.adjacency_list[current_node];
// /// Chooses a random available direction at the current intersection.
// fn choose_random_direction(&mut self, graph: &Graph) {
// let current_node = self.traverser.position.from_node_id();
// let intersection = &graph.adjacency_list[current_node];
// Collect all available directions
let mut available_directions = SmallVec::<[_; 4]>::new();
for direction in Direction::DIRECTIONS {
if let Some(edge) = intersection.get(direction) {
if can_ghost_traverse(edge) {
available_directions.push(direction);
}
}
}
// Choose a random direction (avoid reversing unless necessary)
if !available_directions.is_empty() {
let mut rng = SmallRng::from_os_rng();
// // Collect all available directions
// let mut available_directions = SmallVec::<[_; 4]>::new();
// for direction in Direction::DIRECTIONS {
// if let Some(edge) = intersection.get(direction) {
// if can_ghost_traverse(edge) {
// available_directions.push(direction);
// }
// }
// }
// // Choose a random direction (avoid reversing unless necessary)
// if !available_directions.is_empty() {
// let mut rng = SmallRng::from_os_rng();
// Filter out the opposite direction if possible, but allow it if we have limited options
let opposite = self.traverser.direction.opposite();
let filtered_directions: Vec<_> = available_directions
.iter()
.filter(|&&dir| dir != opposite || available_directions.len() <= 2)
.collect();
// // Filter out the opposite direction if possible, but allow it if we have limited options
// let opposite = self.traverser.direction.opposite();
// let filtered_directions: Vec<_> = available_directions
// .iter()
// .filter(|&&dir| dir != opposite || available_directions.len() <= 2)
// .collect();
if let Some(&random_direction) = filtered_directions.choose(&mut rng) {
self.traverser.set_next_direction(*random_direction);
}
}
}
// if let Some(&random_direction) = filtered_directions.choose(&mut rng) {
// self.traverser.set_next_direction(*random_direction);
// }
// }
// }
/// Calculates the shortest path from the ghost's current position to a target node using Dijkstra's algorithm.
///
/// Returns a vector of NodeIds representing the path, or an error if pathfinding fails.
/// The path includes the current node and the target node.
pub fn calculate_path_to_target(&self, graph: &Graph, target: NodeId) -> GameResult<Vec<NodeId>> {
let start_node = self.traverser.position.from_node_id();
// /// Calculates the shortest path from the ghost's current position to a target node using Dijkstra's algorithm.
// ///
// /// Returns a vector of NodeIds representing the path, or an error if pathfinding fails.
// /// The path includes the current node and the target node.
// pub fn calculate_path_to_target(&self, graph: &Graph, target: NodeId) -> GameResult<Vec<NodeId>> {
// let start_node = self.traverser.position.from_node_id();
// Use Dijkstra's algorithm to find the shortest path
let result = dijkstra(
&start_node,
|&node_id| {
// Get all edges from the current node
graph.adjacency_list[node_id]
.edges()
.filter(|edge| can_ghost_traverse(*edge))
.map(|edge| (edge.target, (edge.distance * 100.0) as u32))
.collect::<Vec<_>>()
},
|&node_id| node_id == target,
);
// // Use Dijkstra's algorithm to find the shortest path
// let result = dijkstra(
// &start_node,
// |&node_id| {
// // Get all edges from the current node
// graph.adjacency_list[node_id]
// .edges()
// .filter(|edge| can_ghost_traverse(*edge))
// .map(|edge| (edge.target, (edge.distance * 100.0) as u32))
// .collect::<Vec<_>>()
// },
// |&node_id| node_id == target,
// );
result.map(|(path, _cost)| path).ok_or_else(|| {
GameError::Entity(EntityError::PathfindingFailed(format!(
"No path found from node {} to target {}",
start_node, target
)))
})
}
// result.map(|(path, _cost)| path).ok_or_else(|| {
// GameError::Entity(EntityError::PathfindingFailed(format!(
// "No path found from node {} to target {}",
// start_node, target
// )))
// })
// }
/// Returns the ghost's color for debug rendering.
pub fn debug_color(&self) -> sdl2::pixels::Color {
match self.ghost_type {
GhostType::Blinky => sdl2::pixels::Color::RGB(255, 0, 0), // Red
GhostType::Pinky => sdl2::pixels::Color::RGB(255, 182, 255), // Pink
GhostType::Inky => sdl2::pixels::Color::RGB(0, 255, 255), // Cyan
GhostType::Clyde => sdl2::pixels::Color::RGB(255, 182, 85), // Orange
}
}
}
// /// Returns the ghost's color for debug rendering.
// pub fn debug_color(&self) -> sdl2::pixels::Color {
// match self.ghost_type {
// GhostType::Blinky => sdl2::pixels::Color::RGB(255, 0, 0), // Red
// GhostType::Pinky => sdl2::pixels::Color::RGB(255, 182, 255), // Pink
// GhostType::Inky => sdl2::pixels::Color::RGB(0, 255, 255), // Cyan
// GhostType::Clyde => sdl2::pixels::Color::RGB(255, 182, 85), // Orange
// }
// }
// }
impl Collidable for Ghost {
fn position(&self) -> crate::entity::traversal::Position {
self.traverser.position
}
}
// impl Collidable for Ghost {
// fn position(&self) -> crate::entity::traversal::Position {
// self.traverser.position
// }
// }

5
src/entity/graph.rs
View File

@@ -1,9 +1,8 @@
use glam::Vec2;
use super::direction::Direction;
use crate::ecs::NodeId;
/// A unique identifier for a node, represented by its index in the graph's storage.
pub type NodeId = usize;
use super::direction::Direction;
/// Defines who can traverse a given edge.
#[derive(Debug, Clone, Copy, PartialEq, Eq, Default)]

206
src/entity/item.rs
View File

@@ -1,117 +1,117 @@
use crate::{
constants,
entity::{collision::Collidable, graph::Graph},
error::{EntityError, GameResult},
texture::sprite::{Sprite, SpriteAtlas},
};
use sdl2::render::{Canvas, RenderTarget};
use strum_macros::{EnumCount, EnumIter};
// use crate::{
// constants,
// entity::{collision::Collidable, graph::Graph},
// error::{EntityError, GameResult},
// texture::sprite::{Sprite, SpriteAtlas},
// };
// use sdl2::render::{Canvas, RenderTarget};
// use strum_macros::{EnumCount, EnumIter};
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub enum ItemType {
Pellet,
Energizer,
#[allow(dead_code)]
Fruit {
kind: FruitKind,
},
}
// #[derive(Debug, Clone, Copy, PartialEq, Eq)]
// pub enum ItemType {
// Pellet,
// Energizer,
// #[allow(dead_code)]
// Fruit {
// kind: FruitKind,
// },
// }
impl ItemType {
pub fn get_score(self) -> u32 {
match self {
ItemType::Pellet => 10,
ItemType::Energizer => 50,
ItemType::Fruit { kind } => kind.get_score(),
}
}
}
// impl ItemType {
// pub fn get_score(self) -> u32 {
// match self {
// ItemType::Pellet => 10,
// ItemType::Energizer => 50,
// ItemType::Fruit { kind } => kind.get_score(),
// }
// }
// }
#[derive(Debug, Clone, Copy, PartialEq, Eq, EnumIter, EnumCount)]
#[allow(dead_code)]
pub enum FruitKind {
Apple,
Strawberry,
Orange,
Melon,
Bell,
Key,
Galaxian,
}
// #[derive(Debug, Clone, Copy, PartialEq, Eq, EnumIter, EnumCount)]
// #[allow(dead_code)]
// pub enum FruitKind {
// Apple,
// Strawberry,
// Orange,
// Melon,
// Bell,
// Key,
// Galaxian,
// }
impl FruitKind {
#[allow(dead_code)]
pub fn index(self) -> u8 {
match self {
FruitKind::Apple => 0,
FruitKind::Strawberry => 1,
FruitKind::Orange => 2,
FruitKind::Melon => 3,
FruitKind::Bell => 4,
FruitKind::Key => 5,
FruitKind::Galaxian => 6,
}
}
// impl FruitKind {
// #[allow(dead_code)]
// pub fn index(self) -> u8 {
// match self {
// FruitKind::Apple => 0,
// FruitKind::Strawberry => 1,
// FruitKind::Orange => 2,
// FruitKind::Melon => 3,
// FruitKind::Bell => 4,
// FruitKind::Key => 5,
// FruitKind::Galaxian => 6,
// }
// }
pub fn get_score(self) -> u32 {
match self {
FruitKind::Apple => 100,
FruitKind::Strawberry => 300,
FruitKind::Orange => 500,
FruitKind::Melon => 700,
FruitKind::Bell => 1000,
FruitKind::Key => 2000,
FruitKind::Galaxian => 3000,
}
}
}
// pub fn get_score(self) -> u32 {
// match self {
// FruitKind::Apple => 100,
// FruitKind::Strawberry => 300,
// FruitKind::Orange => 500,
// FruitKind::Melon => 700,
// FruitKind::Bell => 1000,
// FruitKind::Key => 2000,
// FruitKind::Galaxian => 3000,
// }
// }
// }
pub struct Item {
pub node_index: usize,
pub item_type: ItemType,
pub sprite: Sprite,
pub collected: bool,
}
// pub struct Item {
// pub node_index: usize,
// pub item_type: ItemType,
// pub sprite: Sprite,
// pub collected: bool,
// }
impl Item {
pub fn new(node_index: usize, item_type: ItemType, sprite: Sprite) -> Self {
Self {
node_index,
item_type,
sprite,
collected: false,
}
}
// impl Item {
// pub fn new(node_index: usize, item_type: ItemType, sprite: Sprite) -> Self {
// Self {
// node_index,
// item_type,
// sprite,
// collected: false,
// }
// }
pub fn is_collected(&self) -> bool {
self.collected
}
// pub fn is_collected(&self) -> bool {
// self.collected
// }
pub fn collect(&mut self) {
self.collected = true;
}
// pub fn collect(&mut self) {
// self.collected = true;
// }
pub fn get_score(&self) -> u32 {
self.item_type.get_score()
}
// pub fn get_score(&self) -> u32 {
// self.item_type.get_score()
// }
pub fn render<T: RenderTarget>(&self, canvas: &mut Canvas<T>, atlas: &mut SpriteAtlas, graph: &Graph) -> GameResult<()> {
if self.collected {
return Ok(());
}
// pub fn render<T: RenderTarget>(&self, canvas: &mut Canvas<T>, atlas: &mut SpriteAtlas, graph: &Graph) -> GameResult<()> {
// if self.collected {
// return Ok(());
// }
let node = graph
.get_node(self.node_index)
.ok_or(EntityError::NodeNotFound(self.node_index))?;
let position = node.position + constants::BOARD_PIXEL_OFFSET.as_vec2();
// let node = graph
// .get_node(self.node_index)
// .ok_or(EntityError::NodeNotFound(self.node_index))?;
// let position = node.position + constants::BOARD_PIXEL_OFFSET.as_vec2();
self.sprite.render(canvas, atlas, position)?;
Ok(())
}
}
// self.sprite.render(canvas, atlas, position)?;
// Ok(())
// }
// }
impl Collidable for Item {
fn position(&self) -> crate::entity::traversal::Position {
crate::entity::traversal::Position::AtNode(self.node_index)
}
}
// impl Collidable for Item {
// fn position(&self) -> crate::entity::traversal::Position {
// crate::entity::traversal::Position::AtNode(self.node_index)
// }
// }

215
src/entity/pacman.rs
View File

@@ -1,134 +1,115 @@
//! Pac-Man entity implementation.
//!
//! This module contains the main player character logic, including movement,
//! animation, and rendering. Pac-Man moves through the game graph using
//! a traverser and displays directional animated textures.
// //! Pac-Man entity implementation.
// //!
// //! This module contains the main player character logic, including movement,
// //! animation, and rendering. Pac-Man moves through the game graph using
// //! a traverser and displays directional animated textures.
use crate::entity::{
collision::Collidable,
direction::Direction,
graph::{Edge, EdgePermissions, Graph, NodeId},
r#trait::Entity,
traversal::Traverser,
};
use crate::texture::animated::AnimatedTexture;
use crate::texture::directional::DirectionalAnimatedTexture;
use crate::texture::sprite::SpriteAtlas;
use sdl2::keyboard::Keycode;
use tracing::error;
// use crate::entity::{
// collision::Collidable,
// direction::Direction,
// graph::{Edge, EdgePermissions, Graph, NodeId},
// r#trait::Entity,
// traversal::Traverser,
// };
// use crate::texture::animated::AnimatedTexture;
// use crate::texture::directional::DirectionalAnimatedTexture;
// use crate::texture::sprite::SpriteAtlas;
// use tracing::error;
use crate::error::{GameError, GameResult, TextureError};
// use crate::error::{GameError, GameResult, TextureError};
/// Determines if Pac-Man can traverse a given edge.
///
/// Pac-Man can only move through edges that allow all entities.
fn can_pacman_traverse(edge: Edge) -> bool {
matches!(edge.permissions, EdgePermissions::All)
}
// /// Determines if Pac-Man can traverse a given edge.
// ///
// /// Pac-Man can only move through edges that allow all entities.
// fn can_pacman_traverse(edge: Edge) -> bool {
// matches!(edge.permissions, EdgePermissions::All)
// }
/// The main player character entity.
///
/// Pac-Man moves through the game world using a graph-based navigation system
/// and displays directional animated sprites based on movement state.
pub struct Pacman {
/// Handles movement through the game graph
pub traverser: Traverser,
/// Manages directional animated textures for different movement states
texture: DirectionalAnimatedTexture,
}
// /// The main player character entity.
// ///
// /// Pac-Man moves through the game world using a graph-based navigation system
// /// and displays directional animated sprites based on movement state.
// pub struct Pacman {
// /// Handles movement through the game graph
// pub traverser: Traverser,
// /// Manages directional animated textures for different movement states
// texture: DirectionalAnimatedTexture,
// }
impl Entity for Pacman {
fn traverser(&self) -> &Traverser {
&self.traverser
}
// impl Entity for Pacman {
// fn traverser(&self) -> &Traverser {
// &self.traverser
// }
fn traverser_mut(&mut self) -> &mut Traverser {
&mut self.traverser
}
// fn traverser_mut(&mut self) -> &mut Traverser {
// &mut self.traverser
// }
fn texture(&self) -> &DirectionalAnimatedTexture {
&self.texture
}
// fn texture(&self) -> &DirectionalAnimatedTexture {
// &self.texture
// }
fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture {
&mut self.texture
}
// fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture {
// &mut self.texture
// }
fn speed(&self) -> f32 {
1.125
}
// fn speed(&self) -> f32 {
// 1.125
// }
fn can_traverse(&self, edge: Edge) -> bool {
can_pacman_traverse(edge)
}
// fn can_traverse(&self, edge: Edge) -> bool {
// can_pacman_traverse(edge)
// }
fn tick(&mut self, dt: f32, graph: &Graph) {
if let Err(e) = self.traverser.advance(graph, dt * 60.0 * 1.125, &can_pacman_traverse) {
error!("Pac-Man movement error: {}", e);
}
self.texture.tick(dt);
}
}
// fn tick(&mut self, dt: f32, graph: &Graph) {
// if let Err(e) = self.traverser.advance(graph, dt * 60.0 * 1.125, &can_pacman_traverse) {
// error!("Pac-Man movement error: {}", e);
// }
// self.texture.tick(dt);
// }
// }
impl Pacman {
/// Creates a new Pac-Man instance at the specified starting node.
///
/// Sets up animated textures for all four directions with moving and stopped states.
/// The moving animation cycles through open mouth, closed mouth, and full sprites.
pub fn new(graph: &Graph, start_node: NodeId, atlas: &SpriteAtlas) -> GameResult<Self> {
let mut textures = [None, None, None, None];
let mut stopped_textures = [None, None, None, None];
// impl Pacman {
// /// Creates a new Pac-Man instance at the specified starting node.
// ///
// /// Sets up animated textures for all four directions with moving and stopped states.
// /// The moving animation cycles through open mouth, closed mouth, and full sprites.
// pub fn new(graph: &Graph, start_node: NodeId, atlas: &SpriteAtlas) -> GameResult<Self> {
// let mut textures = [None, None, None, None];
// let mut stopped_textures = [None, None, None, None];
for direction in Direction::DIRECTIONS {
let moving_prefix = match direction {
Direction::Up => "pacman/up",
Direction::Down => "pacman/down",
Direction::Left => "pacman/left",
Direction::Right => "pacman/right",
};
let moving_tiles = vec![
SpriteAtlas::get_tile(atlas, &format!("{moving_prefix}_a.png"))
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_a.png"))))?,
SpriteAtlas::get_tile(atlas, &format!("{moving_prefix}_b.png"))
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_b.png"))))?,
SpriteAtlas::get_tile(atlas, "pacman/full.png")
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound("pacman/full.png".to_string())))?,
];
// for direction in Direction::DIRECTIONS {
// let moving_prefix = match direction {
// Direction::Up => "pacman/up",
// Direction::Down => "pacman/down",
// Direction::Left => "pacman/left",
// Direction::Right => "pacman/right",
// };
// let moving_tiles = vec![
// SpriteAtlas::get_tile(atlas, &format!("{moving_prefix}_a.png"))
// .ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_a.png"))))?,
// SpriteAtlas::get_tile(atlas, &format!("{moving_prefix}_b.png"))
// .ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_b.png"))))?,
// SpriteAtlas::get_tile(atlas, "pacman/full.png")
// .ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound("pacman/full.png".to_string())))?,
// ];
let stopped_tiles = vec![SpriteAtlas::get_tile(atlas, &format!("{moving_prefix}_b.png"))
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_b.png"))))?];
// let stopped_tiles = vec![SpriteAtlas::get_tile(atlas, &format!("{moving_prefix}_b.png"))
// .ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_b.png"))))?];
textures[direction.as_usize()] = Some(AnimatedTexture::new(moving_tiles, 0.08)?);
stopped_textures[direction.as_usize()] = Some(AnimatedTexture::new(stopped_tiles, 0.1)?);
}
// textures[direction.as_usize()] = Some(AnimatedTexture::new(moving_tiles, 0.08)?);
// stopped_textures[direction.as_usize()] = Some(AnimatedTexture::new(stopped_tiles, 0.1)?);
// }
Ok(Self {
traverser: Traverser::new(graph, start_node, Direction::Left, &can_pacman_traverse),
texture: DirectionalAnimatedTexture::new(textures, stopped_textures),
})
}
// Ok(Self {
// traverser: Traverser::new(graph, start_node, Direction::Left, &can_pacman_traverse),
// texture: DirectionalAnimatedTexture::new(textures, stopped_textures),
// })
// }
// }
/// Handles keyboard input to change Pac-Man's direction.
///
/// Maps arrow keys to directions and queues the direction change
/// for the next valid intersection.
pub fn handle_key(&mut self, keycode: Keycode) {
let direction = match keycode {
Keycode::Up => Some(Direction::Up),
Keycode::Down => Some(Direction::Down),
Keycode::Left => Some(Direction::Left),
Keycode::Right => Some(Direction::Right),
_ => None,
};
if let Some(direction) = direction {
self.traverser.set_next_direction(direction);
}
}
}
impl Collidable for Pacman {
fn position(&self) -> crate::entity::traversal::Position {
self.traverser.position
}
}
// impl Collidable for Pacman {
// fn position(&self) -> crate::entity::traversal::Position {
// self.traverser.position
// }
// }

196
src/entity/trait.rs
View File

@@ -1,114 +1,114 @@
//! Entity trait for common movement and rendering functionality.
//!
//! This module defines a trait that captures the shared behavior between
//! different game entities like Ghosts and Pac-Man, including movement,
//! rendering, and position calculations.
// //! Entity trait for common movement and rendering functionality.
// //!
// //! This module defines a trait that captures the shared behavior between
// //! different game entities like Ghosts and Pac-Man, including movement,
// //! rendering, and position calculations.
use glam::Vec2;
use sdl2::render::{Canvas, RenderTarget};
// use glam::Vec2;
// use sdl2::render::{Canvas, RenderTarget};
use crate::entity::direction::Direction;
use crate::entity::graph::{Edge, Graph, NodeId};
use crate::entity::traversal::{Position, Traverser};
use crate::error::{EntityError, GameError, GameResult, TextureError};
use crate::texture::directional::DirectionalAnimatedTexture;
use crate::texture::sprite::SpriteAtlas;
// use crate::entity::direction::Direction;
// use crate::entity::graph::{Edge, Graph, NodeId};
// use crate::entity::traversal::{Position, Traverser};
// use crate::error::{EntityError, GameError, GameResult, TextureError};
// use crate::texture::directional::DirectionalAnimatedTexture;
// use crate::texture::sprite::SpriteAtlas;
/// Trait defining common functionality for game entities that move through the graph.
///
/// This trait provides a unified interface for entities that:
/// - Move through the game graph using a traverser
/// - Render using directional animated textures
/// - Have position calculations and movement speed
#[allow(dead_code)]
pub trait Entity {
/// Returns a reference to the entity's traverser for movement control.
fn traverser(&self) -> &Traverser;
// /// Trait defining common functionality for game entities that move through the graph.
// ///
// /// This trait provides a unified interface for entities that:
// /// - Move through the game graph using a traverser
// /// - Render using directional animated textures
// /// - Have position calculations and movement speed
// #[allow(dead_code)]
// pub trait Entity {
// /// Returns a reference to the entity's traverser for movement control.
// fn traverser(&self) -> &Traverser;
/// Returns a mutable reference to the entity's traverser for movement control.
fn traverser_mut(&mut self) -> &mut Traverser;
// /// Returns a mutable reference to the entity's traverser for movement control.
// fn traverser_mut(&mut self) -> &mut Traverser;
/// Returns a reference to the entity's directional animated texture.
fn texture(&self) -> &DirectionalAnimatedTexture;
// /// Returns a reference to the entity's directional animated texture.
// fn texture(&self) -> &DirectionalAnimatedTexture;
/// Returns a mutable reference to the entity's directional animated texture.
fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture;
// /// Returns a mutable reference to the entity's directional animated texture.
// fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture;
/// Returns the movement speed multiplier for this entity.
fn speed(&self) -> f32;
// /// Returns the movement speed multiplier for this entity.
// fn speed(&self) -> f32;
/// Determines if this entity can traverse a given edge.
fn can_traverse(&self, edge: Edge) -> bool;
// /// Determines if this entity can traverse a given edge.
// fn can_traverse(&self, edge: Edge) -> bool;
/// Updates the entity's position and animation state.
///
/// This method advances movement through the graph and updates texture animation.
fn tick(&mut self, dt: f32, graph: &Graph);
// /// Updates the entity's position and animation state.
// ///
// /// This method advances movement through the graph and updates texture animation.
// fn tick(&mut self, dt: f32, graph: &Graph);
/// Calculates the current pixel position in the game world.
///
/// Converts the graph position to screen coordinates, accounting for
/// the board offset and centering the sprite.
fn get_pixel_pos(&self, graph: &Graph) -> GameResult<Vec2> {
let pos = match self.traverser().position {
Position::AtNode(node_id) => {
let node = graph.get_node(node_id).ok_or(EntityError::NodeNotFound(node_id))?;
node.position
}
Position::BetweenNodes { from, to, traversed } => {
let from_node = graph.get_node(from).ok_or(EntityError::NodeNotFound(from))?;
let to_node = graph.get_node(to).ok_or(EntityError::NodeNotFound(to))?;
let edge = graph.find_edge(from, to).ok_or(EntityError::EdgeNotFound { from, to })?;
from_node.position + (to_node.position - from_node.position) * (traversed / edge.distance)
}
};
// /// Calculates the current pixel position in the game world.
// ///
// /// Converts the graph position to screen coordinates, accounting for
// /// the board offset and centering the sprite.
// fn get_pixel_pos(&self, graph: &Graph) -> GameResult<Vec2> {
// let pos = match self.traverser().position {
// Position::AtNode(node_id) => {
// let node = graph.get_node(node_id).ok_or(EntityError::NodeNotFound(node_id))?;
// node.position
// }
// Position::BetweenNodes { from, to, traversed } => {
// let from_node = graph.get_node(from).ok_or(EntityError::NodeNotFound(from))?;
// let to_node = graph.get_node(to).ok_or(EntityError::NodeNotFound(to))?;
// let edge = graph.find_edge(from, to).ok_or(EntityError::EdgeNotFound { from, to })?;
// from_node.position + (to_node.position - from_node.position) * (traversed / edge.distance)
// }
// };
Ok(Vec2::new(
pos.x + crate::constants::BOARD_PIXEL_OFFSET.x as f32,
pos.y + crate::constants::BOARD_PIXEL_OFFSET.y as f32,
))
}
// Ok(Vec2::new(
// pos.x + crate::constants::BOARD_PIXEL_OFFSET.x as f32,
// pos.y + crate::constants::BOARD_PIXEL_OFFSET.y as f32,
// ))
// }
/// Returns the current node ID that the entity is at or moving towards.
///
/// If the entity is at a node, returns that node ID.
/// If the entity is between nodes, returns the node it's moving towards.
fn current_node_id(&self) -> NodeId {
match self.traverser().position {
Position::AtNode(node_id) => node_id,
Position::BetweenNodes { to, .. } => to,
}
}
// /// Returns the current node ID that the entity is at or moving towards.
// ///
// /// If the entity is at a node, returns that node ID.
// /// If the entity is between nodes, returns the node it's moving towards.
// fn current_node_id(&self) -> NodeId {
// match self.traverser().position {
// Position::AtNode(node_id) => node_id,
// Position::BetweenNodes { to, .. } => to,
// }
// }
/// Sets the next direction for the entity to take.
///
/// The direction is buffered and will be applied at the next opportunity,
/// typically when the entity reaches a new node.
fn set_next_direction(&mut self, direction: Direction) {
self.traverser_mut().set_next_direction(direction);
}
// /// Sets the next direction for the entity to take.
// ///
// /// The direction is buffered and will be applied at the next opportunity,
// /// typically when the entity reaches a new node.
// fn set_next_direction(&mut self, direction: Direction) {
// self.traverser_mut().set_next_direction(direction);
// }
/// Renders the entity at its current position.
///
/// Draws the appropriate directional sprite based on the entity's
/// current movement state and direction.
fn render<T: RenderTarget>(&self, canvas: &mut Canvas<T>, atlas: &mut SpriteAtlas, graph: &Graph) -> GameResult<()> {
let pixel_pos = self.get_pixel_pos(graph)?;
let dest = crate::helpers::centered_with_size(
glam::IVec2::new(pixel_pos.x as i32, pixel_pos.y as i32),
glam::UVec2::new(16, 16),
);
// /// Renders the entity at its current position.
// ///
// /// Draws the appropriate directional sprite based on the entity's
// /// current movement state and direction.
// fn render<T: RenderTarget>(&self, canvas: &mut Canvas<T>, atlas: &mut SpriteAtlas, graph: &Graph) -> GameResult<()> {
// let pixel_pos = self.get_pixel_pos(graph)?;
// let dest = crate::helpers::centered_with_size(
// glam::IVec2::new(pixel_pos.x as i32, pixel_pos.y as i32),
// glam::UVec2::new(16, 16),
// );
if self.traverser().position.is_stopped() {
self.texture()
.render_stopped(canvas, atlas, dest, self.traverser().direction)
.map_err(|e| GameError::Texture(TextureError::RenderFailed(e.to_string())))?;
} else {
self.texture()
.render(canvas, atlas, dest, self.traverser().direction)
.map_err(|e| GameError::Texture(TextureError::RenderFailed(e.to_string())))?;
}
// if self.traverser().position.is_stopped() {
// self.texture()
// .render_stopped(canvas, atlas, dest, self.traverser().direction)
// .map_err(|e| GameError::Texture(TextureError::RenderFailed(e.to_string())))?;
// } else {
// self.texture()
// .render(canvas, atlas, dest, self.traverser().direction)
// .map_err(|e| GameError::Texture(TextureError::RenderFailed(e.to_string())))?;
// }
Ok(())
}
}
// Ok(())
// }
// }

376
src/entity/traversal.rs
View File

@@ -1,229 +1,181 @@
use tracing::error;
// use tracing::error;
use crate::error::GameResult;
// use crate::error::GameResult;
use super::direction::Direction;
use super::graph::{Edge, Graph, NodeId};
// use super::direction::Direction;
// use super::graph::{Edge, Graph, NodeId};
/// Represents the current position of an entity traversing the graph.
///
/// This enum allows for precise tracking of whether an entity is exactly at a node
/// or moving along an edge between two nodes.
#[derive(Debug, PartialEq, Clone, Copy)]
pub enum Position {
/// The traverser is located exactly at a node.
AtNode(NodeId),
/// The traverser is on an edge between two nodes.
BetweenNodes {
from: NodeId,
to: NodeId,
/// The floating-point distance traversed along the edge from the `from` node.
traversed: f32,
},
}
// /// Manages an entity's movement through the graph.
// ///
// /// A `Traverser` encapsulates the state of an entity's position and direction,
// /// providing a way to advance along the graph's paths based on a given distance.
// /// It also handles direction changes, buffering the next intended direction.
// pub struct Traverser {
// /// The current position of the traverser in the graph.
// pub position: Position,
// /// The current direction of movement.
// pub direction: Direction,
// /// Buffered direction change with remaining frame count for timing.
// ///
// /// The `u8` value represents the number of frames remaining before
// /// the buffered direction expires. This allows for responsive controls
// /// by storing direction changes for a limited time.
// pub next_direction: Option<(Direction, u8)>,
// }
#[allow(dead_code)]
impl Position {
/// Returns `true` if the position is exactly at a node.
pub fn is_at_node(&self) -> bool {
matches!(self, Position::AtNode(_))
}
// impl Traverser {
// /// Creates a new traverser starting at the given node ID.
// ///
// /// The traverser will immediately attempt to start moving in the initial direction.
// pub fn new<F>(graph: &Graph, start_node: NodeId, initial_direction: Direction, can_traverse: &F) -> Self
// where
// F: Fn(Edge) -> bool,
// {
// let mut traverser = Traverser {
// position: Position::AtNode(start_node),
// direction: initial_direction,
// next_direction: Some((initial_direction, 1)),
// };
/// Returns the `NodeId` of the current or most recently departed node.
#[allow(clippy::wrong_self_convention)]
pub fn from_node_id(&self) -> NodeId {
match self {
Position::AtNode(id) => *id,
Position::BetweenNodes { from, .. } => *from,
}
}
// // This will kickstart the traverser into motion
// if let Err(e) = traverser.advance(graph, 0.0, can_traverse) {
// error!("Traverser initialization error: {}", e);
// }
/// Returns the `NodeId` of the destination node, if currently on an edge.
#[allow(clippy::wrong_self_convention)]
pub fn to_node_id(&self) -> Option<NodeId> {
match self {
Position::AtNode(_) => None,
Position::BetweenNodes { to, .. } => Some(*to),
}
}
// traverser
// }
/// Returns `true` if the traverser is stopped at a node.
pub fn is_stopped(&self) -> bool {
matches!(self, Position::AtNode(_))
}
}
// /// Sets the next direction for the traverser to take.
// ///
// /// The direction is buffered and will be applied at the next opportunity,
// /// typically when the traverser reaches a new node. This allows for responsive
// /// controls, as the new direction is stored for a limited time.
// pub fn set_next_direction(&mut self, new_direction: Direction) {
// if self.direction != new_direction {
// self.next_direction = Some((new_direction, 30));
// }
// }
/// Manages an entity's movement through the graph.
///
/// A `Traverser` encapsulates the state of an entity's position and direction,
/// providing a way to advance along the graph's paths based on a given distance.
/// It also handles direction changes, buffering the next intended direction.
pub struct Traverser {
/// The current position of the traverser in the graph.
pub position: Position,
/// The current direction of movement.
pub direction: Direction,
/// Buffered direction change with remaining frame count for timing.
///
/// The `u8` value represents the number of frames remaining before
/// the buffered direction expires. This allows for responsive controls
/// by storing direction changes for a limited time.
pub next_direction: Option<(Direction, u8)>,
}
// /// Advances the traverser along the graph by a specified distance.
// ///
// /// This method updates the traverser's position based on its current state
// /// and the distance to travel.
// ///
// /// - If at a node, it checks for a buffered direction to start moving.
// /// - If between nodes, it moves along the current edge.
// /// - If it reaches a node, it attempts to transition to a new edge based on
// /// the buffered direction or by continuing straight.
// /// - If no valid move is possible, it stops at the node.
// ///
// /// Returns an error if the movement is invalid (e.g., trying to move in an impossible direction).
// pub fn advance<F>(&mut self, graph: &Graph, distance: f32, can_traverse: &F) -> GameResult<()>
// where
// F: Fn(Edge) -> bool,
// {
// // Decrement the remaining frames for the next direction
// if let Some((direction, remaining)) = self.next_direction {
// if remaining > 0 {
// self.next_direction = Some((direction, remaining - 1));
// } else {
// self.next_direction = None;
// }
// }
impl Traverser {
/// Creates a new traverser starting at the given node ID.
///
/// The traverser will immediately attempt to start moving in the initial direction.
pub fn new<F>(graph: &Graph, start_node: NodeId, initial_direction: Direction, can_traverse: &F) -> Self
where
F: Fn(Edge) -> bool,
{
let mut traverser = Traverser {
position: Position::AtNode(start_node),
direction: initial_direction,
next_direction: Some((initial_direction, 1)),
};
// match self.position {
// Position::AtNode(node_id) => {
// // We're not moving, but a buffered direction is available.
// if let Some((next_direction, _)) = self.next_direction {
// if let Some(edge) = graph.find_edge_in_direction(node_id, next_direction) {
// if can_traverse(edge) {
// // Start moving in that direction
// self.position = Position::BetweenNodes {
// from: node_id,
// to: edge.target,
// traversed: distance.max(0.0),
// };
// self.direction = next_direction;
// } else {
// return Err(crate::error::GameError::Entity(crate::error::EntityError::InvalidMovement(
// format!(
// "Cannot traverse edge from {} to {} in direction {:?}",
// node_id, edge.target, next_direction
// ),
// )));
// }
// } else {
// return Err(crate::error::GameError::Entity(crate::error::EntityError::InvalidMovement(
// format!("No edge found in direction {:?} from node {}", next_direction, node_id),
// )));
// }
// This will kickstart the traverser into motion
if let Err(e) = traverser.advance(graph, 0.0, can_traverse) {
error!("Traverser initialization error: {}", e);
}
// self.next_direction = None; // Consume the buffered direction regardless of whether we started moving with it
// }
// }
// Position::BetweenNodes { from, to, traversed } => {
// // There is no point in any of the next logic if we don't travel at all
// if distance <= 0.0 {
// return Ok(());
// }
traverser
}
// let edge = graph.find_edge(from, to).ok_or_else(|| {
// crate::error::GameError::Entity(crate::error::EntityError::InvalidMovement(format!(
// "Inconsistent state: Traverser is on a non-existent edge from {} to {}.",
// from, to
// )))
// })?;
/// Sets the next direction for the traverser to take.
///
/// The direction is buffered and will be applied at the next opportunity,
/// typically when the traverser reaches a new node. This allows for responsive
/// controls, as the new direction is stored for a limited time.
pub fn set_next_direction(&mut self, new_direction: Direction) {
if self.direction != new_direction {
self.next_direction = Some((new_direction, 30));
}
}
// let new_traversed = traversed + distance;
/// Advances the traverser along the graph by a specified distance.
///
/// This method updates the traverser's position based on its current state
/// and the distance to travel.
///
/// - If at a node, it checks for a buffered direction to start moving.
/// - If between nodes, it moves along the current edge.
/// - If it reaches a node, it attempts to transition to a new edge based on
/// the buffered direction or by continuing straight.
/// - If no valid move is possible, it stops at the node.
///
/// Returns an error if the movement is invalid (e.g., trying to move in an impossible direction).
pub fn advance<F>(&mut self, graph: &Graph, distance: f32, can_traverse: &F) -> GameResult<()>
where
F: Fn(Edge) -> bool,
{
// Decrement the remaining frames for the next direction
if let Some((direction, remaining)) = self.next_direction {
if remaining > 0 {
self.next_direction = Some((direction, remaining - 1));
} else {
self.next_direction = None;
}
}
// if new_traversed < edge.distance {
// // Still on the same edge, just update the distance.
// self.position = Position::BetweenNodes {
// from,
// to,
// traversed: new_traversed,
// };
// } else {
// let overflow = new_traversed - edge.distance;
// let mut moved = false;
match self.position {
Position::AtNode(node_id) => {
// We're not moving, but a buffered direction is available.
if let Some((next_direction, _)) = self.next_direction {
if let Some(edge) = graph.find_edge_in_direction(node_id, next_direction) {
if can_traverse(edge) {
// Start moving in that direction
self.position = Position::BetweenNodes {
from: node_id,
to: edge.target,
traversed: distance.max(0.0),
};
self.direction = next_direction;
} else {
return Err(crate::error::GameError::Entity(crate::error::EntityError::InvalidMovement(
format!(
"Cannot traverse edge from {} to {} in direction {:?}",
node_id, edge.target, next_direction
),
)));
}
} else {
return Err(crate::error::GameError::Entity(crate::error::EntityError::InvalidMovement(
format!("No edge found in direction {:?} from node {}", next_direction, node_id),
)));
}
// // If we buffered a direction, try to find an edge in that direction
// if let Some((next_dir, _)) = self.next_direction {
// if let Some(edge) = graph.find_edge_in_direction(to, next_dir) {
// if can_traverse(edge) {
// self.position = Position::BetweenNodes {
// from: to,
// to: edge.target,
// traversed: overflow,
// };
self.next_direction = None; // Consume the buffered direction regardless of whether we started moving with it
}
}
Position::BetweenNodes { from, to, traversed } => {
// There is no point in any of the next logic if we don't travel at all
if distance <= 0.0 {
return Ok(());
}
// self.direction = next_dir; // Remember our new direction
// self.next_direction = None; // Consume the buffered direction
// moved = true;
// }
// }
// }
let edge = graph.find_edge(from, to).ok_or_else(|| {
crate::error::GameError::Entity(crate::error::EntityError::InvalidMovement(format!(
"Inconsistent state: Traverser is on a non-existent edge from {} to {}.",
from, to
)))
})?;
// // If we didn't move, try to continue in the current direction
// if !moved {
// if let Some(edge) = graph.find_edge_in_direction(to, self.direction) {
// if can_traverse(edge) {
// self.position = Position::BetweenNodes {
// from: to,
// to: edge.target,
// traversed: overflow,
// };
// } else {
// self.position = Position::AtNode(to);
// self.next_direction = None;
// }
// } else {
// self.position = Position::AtNode(to);
// self.next_direction = None;
// }
// }
// }
// }
// }
let new_traversed = traversed + distance;
if new_traversed < edge.distance {
// Still on the same edge, just update the distance.
self.position = Position::BetweenNodes {
from,
to,
traversed: new_traversed,
};
} else {
let overflow = new_traversed - edge.distance;
let mut moved = false;
// If we buffered a direction, try to find an edge in that direction
if let Some((next_dir, _)) = self.next_direction {
if let Some(edge) = graph.find_edge_in_direction(to, next_dir) {
if can_traverse(edge) {
self.position = Position::BetweenNodes {
from: to,
to: edge.target,
traversed: overflow,
};
self.direction = next_dir; // Remember our new direction
self.next_direction = None; // Consume the buffered direction
moved = true;
}
}
}
// If we didn't move, try to continue in the current direction
if !moved {
if let Some(edge) = graph.find_edge_in_direction(to, self.direction) {
if can_traverse(edge) {
self.position = Position::BetweenNodes {
from: to,
to: edge.target,
traversed: overflow,
};
} else {
self.position = Position::AtNode(to);
self.next_direction = None;
}
} else {
self.position = Position::AtNode(to);
self.next_direction = None;
}
}
}
}
}
Ok(())
}
}
// Ok(())
// }
// }

4
src/error.rs
View File

@@ -5,11 +5,13 @@
use std::io;
use bevy_ecs::event::Event;
/// Main error type for the Pac-Man game.
///
/// This is the primary error type that should be used in public APIs.
/// It can represent any error that can occur during game operation.
#[derive(thiserror::Error, Debug)]
#[derive(thiserror::Error, Debug, Event)]
pub enum GameError {
#[error("Asset error: {0}")]
Asset(#[from] AssetError),

14
src/game/events.rs Normal file
View File

@@ -0,0 +1,14 @@
use bevy_ecs::event::Event;
use crate::input::commands::GameCommand;
#[derive(Debug, Clone, Copy, Event)]
pub enum GameEvent {
Command(GameCommand),
}
impl From<GameCommand> for GameEvent {
fn from(command: GameCommand) -> Self {
GameEvent::Command(command)
}
}

748
src/game/mod.rs
View File

@@ -1,327 +1,515 @@
//! This module contains the main game logic and state.
use glam::{UVec2, Vec2};
use rand::{rngs::SmallRng, Rng, SeedableRng};
use sdl2::{
keyboard::Keycode,
pixels::Color,
render::{Canvas, RenderTarget, Texture, TextureCreator},
video::WindowContext,
include!(concat!(env!("OUT_DIR"), "/atlas_data.rs"));
use crate::constants::CANVAS_SIZE;
use crate::ecs::interact::interact_system;
use crate::ecs::render::{directional_render_system, render_system, BackbufferResource, MapTextureResource};
use crate::ecs::{DeltaTime, DirectionalAnimated, GlobalState, PlayerBundle, PlayerControlled, Position, Renderable, Velocity};
use crate::entity::direction::Direction;
use crate::entity::{graph, traversal};
use crate::error::{GameError, GameResult, TextureError};
use crate::input::commands::GameCommand;
use crate::map::builder::Map;
use crate::texture::animated::AnimatedTexture;
use crate::texture::directional::DirectionalAnimatedTexture;
use crate::texture::sprite::Sprite;
use bevy_ecs::event::EventRegistry;
use bevy_ecs::observer::Trigger;
use bevy_ecs::schedule::IntoScheduleConfigs;
use bevy_ecs::system::{Commands, ResMut};
use bevy_ecs::{schedule::Schedule, world::World};
use sdl2::image::LoadTexture;
use sdl2::render::{Canvas, ScaleMode, Texture, TextureCreator};
use sdl2::video::{Window, WindowContext};
use sdl2::EventPump;
use crate::asset::{get_asset_bytes, Asset};
use crate::input::{handle_input, Bindings};
use crate::map::render::MapRenderer;
use crate::{
constants,
texture::sprite::{AtlasMapper, AtlasTile, SpriteAtlas},
};
use crate::error::{EntityError, GameError, GameResult};
use crate::entity::{
collision::{Collidable, CollisionSystem, EntityId},
ghost::{Ghost, GhostType},
pacman::Pacman,
r#trait::Entity,
};
use self::events::GameEvent;
pub mod events;
pub mod state;
use state::GameState;
/// The `Game` struct is the main entry point for the game.
///
/// It contains the game's state and logic, and is responsible for
/// handling user input, updating the game state, and rendering the game.
pub struct Game {
state: GameState,
pub world: World,
pub schedule: Schedule,
}
impl Game {
pub fn new(texture_creator: &'static TextureCreator<WindowContext>) -> GameResult<Game> {
let state = GameState::new(texture_creator)?;
pub fn new(
canvas: &'static mut Canvas<Window>,
texture_creator: &'static mut TextureCreator<WindowContext>,
event_pump: &'static mut EventPump,
) -> GameResult<Game> {
let mut world = World::default();
let mut schedule = Schedule::default();
Ok(Game { state })
}
EventRegistry::register_event::<GameError>(&mut world);
EventRegistry::register_event::<GameEvent>(&mut world);
pub fn keyboard_event(&mut self, keycode: Keycode) {
self.state.pacman.handle_key(keycode);
let mut backbuffer = texture_creator
.create_texture_target(None, CANVAS_SIZE.x, CANVAS_SIZE.y)
.map_err(|e| GameError::Sdl(e.to_string()))?;
backbuffer.set_scale_mode(ScaleMode::Nearest);
if keycode == Keycode::M {
self.state.audio.set_mute(!self.state.audio.is_muted());
}
let mut map_texture = texture_creator
.create_texture_target(None, CANVAS_SIZE.x, CANVAS_SIZE.y)
.map_err(|e| GameError::Sdl(e.to_string()))?;
map_texture.set_scale_mode(ScaleMode::Nearest);
if keycode == Keycode::R {
if let Err(e) = self.reset_game_state() {
tracing::error!("Failed to reset game state: {}", e);
// Load atlas and create map texture
let atlas_bytes = get_asset_bytes(Asset::Atlas)?;
let atlas_texture = texture_creator.load_texture_bytes(&atlas_bytes).map_err(|e| {
if e.to_string().contains("format") || e.to_string().contains("unsupported") {
GameError::Texture(crate::error::TextureError::InvalidFormat(format!(
"Unsupported texture format: {e}"
)))
} else {
GameError::Texture(crate::error::TextureError::LoadFailed(e.to_string()))
}
}
}
})?;
/// Resets the game state, randomizing ghost positions and resetting Pac-Man
fn reset_game_state(&mut self) -> GameResult<()> {
let pacman_start_node = self.state.map.start_positions.pacman;
self.state.pacman = Pacman::new(&self.state.map.graph, pacman_start_node, &self.state.atlas)?;
let atlas_mapper = AtlasMapper {
frames: ATLAS_FRAMES.into_iter().map(|(k, v)| (k.to_string(), *v)).collect(),
};
let mut atlas = SpriteAtlas::new(atlas_texture, atlas_mapper);
// Reset items
self.state.items = self.state.map.generate_items(&self.state.atlas)?;
// Randomize ghost positions
let ghost_types = [GhostType::Blinky, GhostType::Pinky, GhostType::Inky, GhostType::Clyde];
let mut rng = SmallRng::from_os_rng();
for (i, ghost) in self.state.ghosts.iter_mut().enumerate() {
let random_node = rng.random_range(0..self.state.map.graph.node_count());
*ghost = Ghost::new(&self.state.map.graph, random_node, ghost_types[i], &self.state.atlas)?;
// Create map tiles
let mut map_tiles = Vec::with_capacity(35);
for i in 0..35 {
let tile_name = format!("maze/tiles/{}.png", i);
let tile = atlas.get_tile(&tile_name).unwrap();
map_tiles.push(tile);
}
// Reset collision system
self.state.collision_system = CollisionSystem::default();
// Re-register Pac-Man
self.state.pacman_id = self.state.collision_system.register_entity(self.state.pacman.position());
// Re-register items
self.state.item_ids.clear();
for item in &self.state.items {
let item_id = self.state.collision_system.register_entity(item.position());
self.state.item_ids.push(item_id);
}
// Re-register ghosts
self.state.ghost_ids.clear();
for ghost in &self.state.ghosts {
let ghost_id = self.state.collision_system.register_entity(ghost.position());
self.state.ghost_ids.push(ghost_id);
}
Ok(())
}
pub fn tick(&mut self, dt: f32) {
self.state.pacman.tick(dt, &self.state.map.graph);
// Update all ghosts
for ghost in &mut self.state.ghosts {
ghost.tick(dt, &self.state.map.graph);
}
// Update collision system positions
self.update_collision_positions();
// Check for collisions
self.check_collisions();
}
/// Toggles the debug mode on and off.
///
/// When debug mode is enabled, the game will render additional information
/// that is useful for debugging, such as the collision grid and entity paths.
pub fn toggle_debug_mode(&mut self) {
self.state.debug_mode = !self.state.debug_mode;
}
fn update_collision_positions(&mut self) {
// Update Pac-Man's position
self.state
.collision_system
.update_position(self.state.pacman_id, self.state.pacman.position());
// Update ghost positions
for (ghost, &ghost_id) in self.state.ghosts.iter().zip(&self.state.ghost_ids) {
self.state.collision_system.update_position(ghost_id, ghost.position());
}
}
fn check_collisions(&mut self) {
// Check Pac-Man vs Items
let potential_collisions = self
.state
.collision_system
.potential_collisions(&self.state.pacman.position());
for entity_id in potential_collisions {
if entity_id != self.state.pacman_id {
// Check if this is an item collision
if let Some(item_index) = self.find_item_by_id(entity_id) {
let item = &mut self.state.items[item_index];
if !item.is_collected() {
item.collect();
self.state.score += item.get_score();
self.state.audio.eat();
// Handle energizer effects
if matches!(item.item_type, crate::entity::item::ItemType::Energizer) {
// TODO: Make ghosts frightened
tracing::info!("Energizer collected! Ghosts should become frightened.");
}
}
}
// Check if this is a ghost collision
if let Some(_ghost_index) = self.find_ghost_by_id(entity_id) {
// TODO: Handle Pac-Man being eaten by ghost
tracing::info!("Pac-Man collided with ghost!");
}
}
}
}
fn find_item_by_id(&self, entity_id: EntityId) -> Option<usize> {
self.state.item_ids.iter().position(|&id| id == entity_id)
}
fn find_ghost_by_id(&self, entity_id: EntityId) -> Option<usize> {
self.state.ghost_ids.iter().position(|&id| id == entity_id)
}
pub fn draw<T: RenderTarget>(&mut self, canvas: &mut Canvas<T>, backbuffer: &mut Texture) -> GameResult<()> {
// Render map to texture
canvas
.with_texture_canvas(backbuffer, |canvas| {
canvas.set_draw_color(Color::BLACK);
canvas.clear();
self.state
.map
.render(canvas, &mut self.state.atlas, &mut self.state.map_tiles);
// Render all items
for item in &self.state.items {
if let Err(e) = item.render(canvas, &mut self.state.atlas, &self.state.map.graph) {
tracing::error!("Failed to render item: {}", e);
}
}
// Render all ghosts
for ghost in &self.state.ghosts {
if let Err(e) = ghost.render(canvas, &mut self.state.atlas, &self.state.map.graph) {
tracing::error!("Failed to render ghost: {}", e);
}
}
if let Err(e) = self.state.pacman.render(canvas, &mut self.state.atlas, &self.state.map.graph) {
tracing::error!("Failed to render pacman: {}", e);
}
.with_texture_canvas(&mut map_texture, |map_canvas| {
MapRenderer::render_map(map_canvas, &mut atlas, &mut map_tiles);
})
.map_err(|e| GameError::Sdl(e.to_string()))?;
Ok(())
}
let map = Map::new(constants::RAW_BOARD)?;
let pacman_start_node = map.start_positions.pacman;
pub fn present_backbuffer<T: RenderTarget>(
&mut self,
canvas: &mut Canvas<T>,
backbuffer: &Texture,
cursor_pos: glam::Vec2,
) -> GameResult<()> {
canvas
.copy(backbuffer, None, None)
.map_err(|e| GameError::Sdl(e.to_string()))?;
if self.state.debug_mode {
if let Err(e) =
self.state
.map
.debug_render_with_cursor(canvas, &mut self.state.text_texture, &mut self.state.atlas, cursor_pos)
{
tracing::error!("Failed to render debug cursor: {}", e);
}
self.render_pathfinding_debug(canvas)?;
let mut textures = [None, None, None, None];
let mut stopped_textures = [None, None, None, None];
for direction in Direction::DIRECTIONS {
let moving_prefix = match direction {
Direction::Up => "pacman/up",
Direction::Down => "pacman/down",
Direction::Left => "pacman/left",
Direction::Right => "pacman/right",
};
let moving_tiles = vec![
SpriteAtlas::get_tile(&atlas, &format!("{moving_prefix}_a.png"))
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_a.png"))))?,
SpriteAtlas::get_tile(&atlas, &format!("{moving_prefix}_b.png"))
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_b.png"))))?,
SpriteAtlas::get_tile(&atlas, "pacman/full.png")
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound("pacman/full.png".to_string())))?,
];
let stopped_tiles = vec![SpriteAtlas::get_tile(&atlas, &format!("{moving_prefix}_b.png"))
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound(format!("{moving_prefix}_b.png"))))?];
textures[direction.as_usize()] = Some(AnimatedTexture::new(moving_tiles, 0.08)?);
stopped_textures[direction.as_usize()] = Some(AnimatedTexture::new(stopped_tiles, 0.1)?);
}
self.draw_hud(canvas)?;
canvas.present();
Ok(())
let player = PlayerBundle {
player: PlayerControlled,
position: Position::AtNode(pacman_start_node),
velocity: Velocity::default(),
sprite: Renderable {
sprite: SpriteAtlas::get_tile(&atlas, "pacman/full.png")
.ok_or_else(|| GameError::Texture(TextureError::AtlasTileNotFound("pacman/full.png".to_string())))?,
layer: 0,
},
directional_animated: DirectionalAnimated {
textures,
stopped_textures,
},
};
world.insert_non_send_resource(atlas);
world.insert_non_send_resource(event_pump);
world.insert_non_send_resource(canvas);
world.insert_non_send_resource(BackbufferResource(backbuffer));
world.insert_non_send_resource(MapTextureResource(map_texture));
world.insert_resource(map);
world.insert_resource(GlobalState { exit: false });
world.insert_resource(Bindings::default());
world.insert_resource(DeltaTime(0f32));
world.add_observer(|event: Trigger<GameEvent>, mut state: ResMut<GlobalState>| match *event {
GameEvent::Command(command) => match command {
GameCommand::Exit => {
state.exit = true;
}
_ => {}
},
});
schedule.add_systems((handle_input, interact_system, directional_render_system, render_system).chain());
// Spawn player
world.spawn(player);
Ok(Game { world, schedule })
}
/// Renders pathfinding debug lines from each ghost to Pac-Man.
// fn handle_command(&mut self, command: crate::input::commands::GameCommand) {
// use crate::input::commands::GameCommand;
// match command {
// GameCommand::MovePlayer(direction) => {
// self.state.pacman.set_next_direction(direction);
// }
// GameCommand::ToggleDebug => {
// self.toggle_debug_mode();
// }
// GameCommand::MuteAudio => {
// let is_muted = self.state.audio.is_muted();
// self.state.audio.set_mute(!is_muted);
// }
// GameCommand::ResetLevel => {
// if let Err(e) = self.reset_game_state() {
// tracing::error!("Failed to reset game state: {}", e);
// }
// }
// GameCommand::TogglePause => {
// self.state.paused = !self.state.paused;
// }
// GameCommand::Exit => {}
// }
// }
// fn process_events(&mut self) {
// while let Some(event) = self.state.event_queue.pop_front() {
// match event {
// GameEvent::Command(command) => self.handle_command(command),
// }
// }
// }
// /// Resets the game state, randomizing ghost positions and resetting Pac-Man
// fn reset_game_state(&mut self) -> GameResult<()> {
// let pacman_start_node = self.state.map.start_positions.pacman;
// self.state.pacman = Pacman::new(&self.state.map.graph, pacman_start_node, &self.state.atlas)?;
// // Reset items
// self.state.items = self.state.map.generate_items(&self.state.atlas)?;
// // Randomize ghost positions
// let ghost_types = [GhostType::Blinky, GhostType::Pinky, GhostType::Inky, GhostType::Clyde];
// let mut rng = SmallRng::from_os_rng();
// for (i, ghost) in self.state.ghosts.iter_mut().enumerate() {
// let random_node = rng.random_range(0..self.state.map.graph.node_count());
// *ghost = Ghost::new(&self.state.map.graph, random_node, ghost_types[i], &self.state.atlas)?;
// }
// // Reset collision system
// self.state.collision_system = CollisionSystem::default();
// // Re-register Pac-Man
// self.state.pacman_id = self.state.collision_system.register_entity(self.state.pacman.position());
// // Re-register items
// self.state.item_ids.clear();
// for item in &self.state.items {
// let item_id = self.state.collision_system.register_entity(item.position());
// self.state.item_ids.push(item_id);
// }
// // Re-register ghosts
// self.state.ghost_ids.clear();
// for ghost in &self.state.ghosts {
// let ghost_id = self.state.collision_system.register_entity(ghost.position());
// self.state.ghost_ids.push(ghost_id);
// }
// Ok(())
// }
/// Ticks the game state.
///
/// Each ghost's path is drawn in its respective color with a small offset
/// to prevent overlapping lines.
fn render_pathfinding_debug<T: RenderTarget>(&self, canvas: &mut Canvas<T>) -> GameResult<()> {
let pacman_node = self.state.pacman.current_node_id();
/// Returns true if the game should exit.
pub fn tick(&mut self, dt: f32) -> bool {
self.world.insert_resource(DeltaTime(dt));
for ghost in self.state.ghosts.iter() {
if let Ok(path) = ghost.calculate_path_to_target(&self.state.map.graph, pacman_node) {
if path.len() < 2 {
continue; // Skip if path is too short
}
// Run all systems
self.schedule.run(&mut self.world);
// Set the ghost's color
canvas.set_draw_color(ghost.debug_color());
let state = self
.world
.get_resource::<GlobalState>()
.expect("GlobalState could not be acquired");
// Calculate offset based on ghost index to prevent overlapping lines
// let offset = (i as f32) * 2.0 - 3.0; // Offset range: -3.0 to 3.0
return state.exit;
// Calculate a consistent offset direction for the entire path
// let first_node = self.map.graph.get_node(path[0]).unwrap();
// let last_node = self.map.graph.get_node(path[path.len() - 1]).unwrap();
// // Process any events that have been posted (such as unpausing)
// self.process_events();
// Use the overall direction from start to end to determine the perpendicular offset
let offset = match ghost.ghost_type {
GhostType::Blinky => Vec2::new(0.25, 0.5),
GhostType::Pinky => Vec2::new(-0.25, -0.25),
GhostType::Inky => Vec2::new(0.5, -0.5),
GhostType::Clyde => Vec2::new(-0.5, 0.25),
} * 5.0;
// // If the game is paused, we don't need to do anything beyond returning
// if self.state.paused {
// return false;
// }
// Calculate offset positions for all nodes using the same perpendicular direction
let mut offset_positions = Vec::new();
for &node_id in &path {
let node = self
.state
.map
.graph
.get_node(node_id)
.ok_or(GameError::Entity(EntityError::NodeNotFound(node_id)))?;
let pos = node.position + crate::constants::BOARD_PIXEL_OFFSET.as_vec2();
offset_positions.push(pos + offset);
}
// self.schedule.run(&mut self.world);
// Draw lines between the offset positions
for window in offset_positions.windows(2) {
if let (Some(from), Some(to)) = (window.first(), window.get(1)) {
// Skip if the distance is too far (used for preventing lines between tunnel portals)
if from.distance_squared(*to) > (crate::constants::CELL_SIZE * 16).pow(2) as f32 {
continue;
}
// self.state.pacman.tick(dt, &self.state.map.graph);
// Draw the line
canvas
.draw_line((from.x as i32, from.y as i32), (to.x as i32, to.y as i32))
.map_err(|e| GameError::Sdl(e.to_string()))?;
}
}
}
}
// // Update all ghosts
// for ghost in &mut self.state.ghosts {
// ghost.tick(dt, &self.state.map.graph);
// }
Ok(())
// // Update collision system positions
// self.update_collision_positions();
// // Check for collisions
// self.check_collisions();
}
fn draw_hud<T: RenderTarget>(&mut self, canvas: &mut Canvas<T>) -> GameResult<()> {
let lives = 3;
let score_text = format!("{:02}", self.state.score);
let x_offset = 4;
let y_offset = 2;
let lives_offset = 3;
let score_offset = 7 - (score_text.len() as i32);
self.state.text_texture.set_scale(1.0);
if let Err(e) = self.state.text_texture.render(
canvas,
&mut self.state.atlas,
&format!("{lives}UP HIGH SCORE "),
UVec2::new(8 * lives_offset as u32 + x_offset, y_offset),
) {
tracing::error!("Failed to render HUD text: {}", e);
}
if let Err(e) = self.state.text_texture.render(
canvas,
&mut self.state.atlas,
&score_text,
UVec2::new(8 * score_offset as u32 + x_offset, 8 + y_offset),
) {
tracing::error!("Failed to render score text: {}", e);
}
// /// Toggles the debug mode on and off.
// ///
// /// When debug mode is enabled, the game will render additional information
// /// that is useful for debugging, such as the collision grid and entity paths.
// pub fn toggle_debug_mode(&mut self) {
// self.state.debug_mode = !self.state.debug_mode;
// }
// Display FPS information in top-left corner
// let fps_text = format!("FPS: {:.1} (1s) / {:.1} (10s)", self.fps_1s, self.fps_10s);
// self.render_text_on(
// canvas,
// &*texture_creator,
// &fps_text,
// IVec2::new(10, 10),
// Color::RGB(255, 255, 0), // Yellow color for FPS display
// );
// fn update_collision_positions(&mut self) {
// // Update Pac-Man's position
// self.state
// .collision_system
// .update_position(self.state.pacman_id, self.state.pacman.position());
Ok(())
}
// // Update ghost positions
// for (ghost, &ghost_id) in self.state.ghosts.iter().zip(&self.state.ghost_ids) {
// self.state.collision_system.update_position(ghost_id, ghost.position());
// }
// }
// fn check_collisions(&mut self) {
// // Check Pac-Man vs Items
// let potential_collisions = self
// .state
// .collision_system
// .potential_collisions(&self.state.pacman.position());
// for entity_id in potential_collisions {
// if entity_id != self.state.pacman_id {
// // Check if this is an item collision
// if let Some(item_index) = self.find_item_by_id(entity_id) {
// let item = &mut self.state.items[item_index];
// if !item.is_collected() {
// item.collect();
// self.state.score += item.get_score();
// self.state.audio.eat();
// // Handle energizer effects
// if matches!(item.item_type, crate::entity::item::ItemType::Energizer) {
// // TODO: Make ghosts frightened
// tracing::info!("Energizer collected! Ghosts should become frightened.");
// }
// }
// }
// // Check if this is a ghost collision
// if let Some(_ghost_index) = self.find_ghost_by_id(entity_id) {
// // TODO: Handle Pac-Man being eaten by ghost
// tracing::info!("Pac-Man collided with ghost!");
// }
// }
// }
// }
// fn find_item_by_id(&self, entity_id: EntityId) -> Option<usize> {
// self.state.item_ids.iter().position(|&id| id == entity_id)
// }
// fn find_ghost_by_id(&self, entity_id: EntityId) -> Option<usize> {
// self.state.ghost_ids.iter().position(|&id| id == entity_id)
// }
// pub fn draw<T: sdl2::render::RenderTarget>(&mut self, canvas: &mut Canvas<T>, backbuffer: &mut Texture) -> GameResult<()> {
// // Only render the map texture once and cache it
// if !self.state.map_rendered {
// let mut map_texture = self
// .state
// .texture_creator
// .create_texture_target(None, constants::CANVAS_SIZE.x, constants::CANVAS_SIZE.y)
// .map_err(|e| crate::error::GameError::Sdl(e.to_string()))?;
// canvas
// .with_texture_canvas(&mut map_texture, |map_canvas| {
// let mut map_tiles = Vec::with_capacity(35);
// for i in 0..35 {
// let tile_name = format!("maze/tiles/{}.png", i);
// let tile = SpriteAtlas::get_tile(&self.state.atlas, &tile_name).unwrap();
// map_tiles.push(tile);
// }
// MapRenderer::render_map(map_canvas, &mut self.state.atlas, &mut map_tiles);
// })
// .map_err(|e| crate::error::GameError::Sdl(e.to_string()))?;
// self.state.map_texture = Some(map_texture);
// self.state.map_rendered = true;
// }
// canvas.set_draw_color(Color::BLACK);
// canvas.clear();
// if let Some(ref map_texture) = self.state.map_texture {
// canvas.copy(map_texture, None, None).unwrap();
// }
// // Render all items
// for item in &self.state.items {
// if let Err(e) = item.render(canvas, &mut self.state.atlas, &self.state.map.graph) {
// tracing::error!("Failed to render item: {}", e);
// }
// }
// // Render all ghosts
// for ghost in &self.state.ghosts {
// if let Err(e) = ghost.render(canvas, &mut self.state.atlas, &self.state.map.graph) {
// tracing::error!("Failed to render ghost: {}", e);
// }
// }
// if let Err(e) = self.state.pacman.render(canvas, &mut self.state.atlas, &self.state.map.graph) {
// tracing::error!("Failed to render pacman: {}", e);
// }
// if self.state.debug_mode {
// if let Err(e) =
// self.state
// .map
// .debug_render_with_cursor(canvas, &mut self.state.text_texture, &mut self.state.atlas, cursor_pos)
// {
// tracing::error!("Failed to render debug cursor: {}", e);
// }
// self.render_pathfinding_debug(canvas)?;
// }
// self.draw_hud(canvas)?;
// canvas.present();
// Ok(())
// }
// /// Renders pathfinding debug lines from each ghost to Pac-Man.
// ///
// /// Each ghost's path is drawn in its respective color with a small offset
// /// to prevent overlapping lines.
// fn render_pathfinding_debug<T: sdl2::render::RenderTarget>(&self, canvas: &mut Canvas<T>) -> GameResult<()> {
// let pacman_node = self.state.pacman.current_node_id();
// for ghost in self.state.ghosts.iter() {
// if let Ok(path) = ghost.calculate_path_to_target(&self.state.map.graph, pacman_node) {
// if path.len() < 2 {
// continue; // Skip if path is too short
// }
// // Set the ghost's color
// canvas.set_draw_color(ghost.debug_color());
// // Calculate offset based on ghost index to prevent overlapping lines
// // let offset = (i as f32) * 2.0 - 3.0; // Offset range: -3.0 to 3.0
// // Calculate a consistent offset direction for the entire path
// // let first_node = self.map.graph.get_node(path[0]).unwrap();
// // let last_node = self.map.graph.get_node(path[path.len() - 1]).unwrap();
// // Use the overall direction from start to end to determine the perpendicular offset
// let offset = match ghost.ghost_type {
// GhostType::Blinky => glam::Vec2::new(0.25, 0.5),
// GhostType::Pinky => glam::Vec2::new(-0.25, -0.25),
// GhostType::Inky => glam::Vec2::new(0.5, -0.5),
// GhostType::Clyde => glam::Vec2::new(-0.5, 0.25),
// } * 5.0;
// // Calculate offset positions for all nodes using the same perpendicular direction
// let mut offset_positions = Vec::new();
// for &node_id in &path {
// let node = self
// .state
// .map
// .graph
// .get_node(node_id)
// .ok_or(crate::error::EntityError::NodeNotFound(node_id))?;
// let pos = node.position + crate::constants::BOARD_PIXEL_OFFSET.as_vec2();
// offset_positions.push(pos + offset);
// }
// // Draw lines between the offset positions
// for window in offset_positions.windows(2) {
// if let (Some(from), Some(to)) = (window.first(), window.get(1)) {
// // Skip if the distance is too far (used for preventing lines between tunnel portals)
// if from.distance_squared(*to) > (crate::constants::CELL_SIZE * 16).pow(2) as f32 {
// continue;
// }
// // Draw the line
// canvas
// .draw_line((from.x as i32, from.y as i32), (to.x as i32, to.y as i32))
// .map_err(|e| crate::error::GameError::Sdl(e.to_string()))?;
// }
// }
// }
// }
// Ok(())
// }
// fn draw_hud<T: sdl2::render::RenderTarget>(&mut self, canvas: &mut Canvas<T>) -> GameResult<()> {
// let lives = 3;
// let score_text = format!("{:02}", self.state.score);
// let x_offset = 4;
// let y_offset = 2;
// let lives_offset = 3;
// let score_offset = 7 - (score_text.len() as i32);
// self.state.text_texture.set_scale(1.0);
// if let Err(e) = self.state.text_texture.render(
// canvas,
// &mut self.state.atlas,
// &format!("{lives}UP HIGH SCORE "),
// glam::UVec2::new(8 * lives_offset as u32 + x_offset, y_offset),
// ) {
// tracing::error!("Failed to render HUD text: {}", e);
// }
// if let Err(e) = self.state.text_texture.render(
// canvas,
// &mut self.state.atlas,
// &score_text,
// glam::UVec2::new(8 * score_offset as u32 + x_offset, 8 + y_offset),
// ) {
// tracing::error!("Failed to render score text: {}", e);
// }
// // Display FPS information in top-left corner
// // let fps_text = format!("FPS: {:.1} (1s) / {:.1} (10s)", self.fps_1s, self.fps_10s);
// // self.render_text_on(
// // canvas,
// // &*texture_creator,
// // &fps_text,
// // IVec2::new(10, 10),
// // Color::RGB(255, 255, 0), // Yellow color for FPS display
// // );
// Ok(())
// }
}

259
src/game/state.rs
View File

@@ -1,140 +1,153 @@
use sdl2::{image::LoadTexture, render::TextureCreator, video::WindowContext};
use smallvec::SmallVec;
// use std::collections::VecDeque;
use crate::{
asset::{get_asset_bytes, Asset},
audio::Audio,
constants::RAW_BOARD,
entity::{
collision::{Collidable, CollisionSystem},
ghost::{Ghost, GhostType},
item::Item,
pacman::Pacman,
},
error::{GameError, GameResult, TextureError},
game::EntityId,
map::Map,
texture::{
sprite::{AtlasMapper, AtlasTile, SpriteAtlas},
text::TextTexture,
},
};
// use sdl2::{
// image::LoadTexture,
// render::{Texture, TextureCreator},
// video::WindowContext,
// };
// use smallvec::SmallVec;
/// The `GameState` struct holds all the essential data for the game.
///
/// This includes the score, map, entities (Pac-Man, ghosts, items),
/// collision system, and rendering resources. By centralizing the game's state,
/// we can cleanly separate it from the game's logic, making it easier to manage
/// and reason about.
pub struct GameState {
pub score: u32,
pub map: Map,
pub map_tiles: Vec<AtlasTile>,
pub pacman: Pacman,
pub pacman_id: EntityId,
pub ghosts: SmallVec<[Ghost; 4]>,
pub ghost_ids: SmallVec<[EntityId; 4]>,
pub items: Vec<Item>,
pub item_ids: Vec<EntityId>,
pub debug_mode: bool,
// use crate::{
// asset::{get_asset_bytes, Asset},
// audio::Audio,
// constants::RAW_BOARD,
// entity::{
// collision::{Collidable, CollisionSystem, EntityId},
// ghost::{Ghost, GhostType},
// item::Item,
// pacman::Pacman,
// },
// error::{GameError, GameResult, TextureError},
// game::events::GameEvent,
// map::builder::Map,
// texture::{
// sprite::{AtlasMapper, SpriteAtlas},
// text::TextTexture,
// },
// };
// Collision system
pub(crate) collision_system: CollisionSystem,
// include!(concat!(env!("OUT_DIR"), "/atlas_data.rs"));
// Rendering resources
pub(crate) atlas: SpriteAtlas,
pub(crate) text_texture: TextTexture,
// /// The `GameState` struct holds all the essential data for the game.
// ///
// /// This includes the score, map, entities (Pac-Man, ghosts, items),
// /// collision system, and rendering resources. By centralizing the game's state,
// /// we can cleanly separate it from the game's logic, making it easier to manage
// /// and reason about.
// pub struct GameState {
// pub paused: bool,
// Audio
pub audio: Audio,
}
// pub score: u32,
// pub map: Map,
// pub pacman: Pacman,
// pub pacman_id: EntityId,
// pub ghosts: SmallVec<[Ghost; 4]>,
// pub ghost_ids: SmallVec<[EntityId; 4]>,
// pub items: Vec<Item>,
// pub item_ids: Vec<EntityId>,
// pub debug_mode: bool,
// pub event_queue: VecDeque<GameEvent>,
impl GameState {
/// Creates a new `GameState` by initializing all the game's data.
///
/// This function sets up the map, Pac-Man, ghosts, items, collision system,
/// and all rendering resources required to start the game. It returns a `GameResult`
/// to handle any potential errors during initialization.
pub fn new(texture_creator: &'static TextureCreator<WindowContext>) -> GameResult<Self> {
let map = Map::new(RAW_BOARD)?;
// // Collision system
// pub(crate) collision_system: CollisionSystem,
let pacman_start_node = map.start_positions.pacman;
// // Rendering resources
// pub(crate) atlas: SpriteAtlas,
// pub(crate) text_texture: TextTexture,
let atlas_bytes = get_asset_bytes(Asset::Atlas)?;
let atlas_texture = texture_creator.load_texture_bytes(&atlas_bytes).map_err(|e| {
if e.to_string().contains("format") || e.to_string().contains("unsupported") {
GameError::Texture(TextureError::InvalidFormat(format!("Unsupported texture format: {e}")))
} else {
GameError::Texture(TextureError::LoadFailed(e.to_string()))
}
})?;
let atlas_json = get_asset_bytes(Asset::AtlasJson)?;
let atlas_mapper: AtlasMapper = serde_json::from_slice(&atlas_json)?;
let atlas = SpriteAtlas::new(atlas_texture, atlas_mapper);
// // Audio
// pub audio: Audio,
let mut map_tiles = Vec::with_capacity(35);
for i in 0..35 {
let tile_name = format!("maze/tiles/{}.png", i);
let tile = SpriteAtlas::get_tile(&atlas, &tile_name)
.ok_or(GameError::Texture(TextureError::AtlasTileNotFound(tile_name)))?;
map_tiles.push(tile);
}
// // Map texture pre-rendering
// pub(crate) map_texture: Option<Texture<'static>>,
// pub(crate) map_rendered: bool,
// pub(crate) texture_creator: &'static TextureCreator<WindowContext>,
// }
let text_texture = TextTexture::new(1.0);
let audio = Audio::new();
let pacman = Pacman::new(&map.graph, pacman_start_node, &atlas)?;
// impl GameState {
// /// Creates a new `GameState` by initializing all the game's data.
// ///
// /// This function sets up the map, Pac-Man, ghosts, items, collision system,
// /// and all rendering resources required to start the game. It returns a `GameResult`
// /// to handle any potential errors during initialization.
// pub fn new(texture_creator: &'static TextureCreator<WindowContext>) -> GameResult<Self> {
// let map = Map::new(RAW_BOARD)?;
// Generate items (pellets and energizers)
let items = map.generate_items(&atlas)?;
// let start_node = map.start_positions.pacman;
// Initialize collision system
let mut collision_system = CollisionSystem::default();
// let atlas_bytes = get_asset_bytes(Asset::Atlas)?;
// let atlas_texture = texture_creator.load_texture_bytes(&atlas_bytes).map_err(|e| {
// if e.to_string().contains("format") || e.to_string().contains("unsupported") {
// GameError::Texture(TextureError::InvalidFormat(format!("Unsupported texture format: {e}")))
// } else {
// GameError::Texture(TextureError::LoadFailed(e.to_string()))
// }
// })?;
// Register Pac-Man
let pacman_id = collision_system.register_entity(pacman.position());
// let atlas_mapper = AtlasMapper {
// frames: ATLAS_FRAMES.into_iter().map(|(k, v)| (k.to_string(), *v)).collect(),
// };
// let atlas = SpriteAtlas::new(atlas_texture, atlas_mapper);
// Register items
let item_ids = items
.iter()
.map(|item| collision_system.register_entity(item.position()))
.collect();
// let text_texture = TextTexture::new(1.0);
// let audio = Audio::new();
// let pacman = Pacman::new(&map.graph, start_node, &atlas)?;
// Create and register ghosts
let ghosts = [GhostType::Blinky, GhostType::Pinky, GhostType::Inky, GhostType::Clyde]
.iter()
.zip(
[
map.start_positions.blinky,
map.start_positions.pinky,
map.start_positions.inky,
map.start_positions.clyde,
]
.iter(),
)
.map(|(ghost_type, start_node)| Ghost::new(&map.graph, *start_node, *ghost_type, &atlas))
.collect::<GameResult<SmallVec<[_; 4]>>>()?;
// // Generate items (pellets and energizers)
// let items = map.generate_items(&atlas)?;
// Register ghosts
let ghost_ids = ghosts
.iter()
.map(|ghost| collision_system.register_entity(ghost.position()))
.collect();
// // Initialize collision system
// let mut collision_system = CollisionSystem::default();
Ok(Self {
map,
atlas,
map_tiles,
pacman,
pacman_id,
ghosts,
ghost_ids,
items,
item_ids,
text_texture,
audio,
score: 0,
debug_mode: false,
collision_system,
})
}
}
// // Register Pac-Man
// let pacman_id = collision_system.register_entity(pacman.position());
// // Register items
// let item_ids = items
// .iter()
// .map(|item| collision_system.register_entity(item.position()))
// .collect();
// // Create and register ghosts
// let ghosts = [GhostType::Blinky, GhostType::Pinky, GhostType::Inky, GhostType::Clyde]
// .iter()
// .zip(
// [
// map.start_positions.blinky,
// map.start_positions.pinky,
// map.start_positions.inky,
// map.start_positions.clyde,
// ]
// .iter(),
// )
// .map(|(ghost_type, start_node)| Ghost::new(&map.graph, *start_node, *ghost_type, &atlas))
// .collect::<GameResult<SmallVec<[_; 4]>>>()?;
// // Register ghosts
// let ghost_ids = ghosts
// .iter()
// .map(|ghost| collision_system.register_entity(ghost.position()))
// .collect();
// Ok(Self {
// paused: false,
// map,
// atlas,
// pacman,
// pacman_id,
// ghosts,
// ghost_ids,
// items,
// item_ids,
// text_texture,
// audio,
// score: 0,
// debug_mode: false,
// collision_system,
// map_texture: None,
// map_rendered: false,
// texture_creator,
// event_queue: VecDeque::new(),
// })
// }
// }

11
src/input/commands.rs Normal file
View File

@@ -0,0 +1,11 @@
use crate::entity::direction::Direction;
#[derive(Debug, Clone, Copy)]
pub enum GameCommand {
MovePlayer(Direction),
Exit,
TogglePause,
ToggleDebug,
MuteAudio,
ResetLevel,
}

61
src/input/mod.rs Normal file
View File

@@ -0,0 +1,61 @@
use std::collections::HashMap;
use bevy_ecs::{
event::EventWriter,
resource::Resource,
system::{Commands, NonSendMut, Res},
};
use sdl2::{event::Event, keyboard::Keycode, EventPump};
use crate::{entity::direction::Direction, game::events::GameEvent, input::commands::GameCommand};
pub mod commands;
#[derive(Debug, Clone, Resource)]
pub struct Bindings {
key_bindings: HashMap<Keycode, GameCommand>,
}
impl Default for Bindings {
fn default() -> Self {
let mut key_bindings = HashMap::new();
// Player movement
key_bindings.insert(Keycode::Up, GameCommand::MovePlayer(Direction::Up));
key_bindings.insert(Keycode::W, GameCommand::MovePlayer(Direction::Up));
key_bindings.insert(Keycode::Down, GameCommand::MovePlayer(Direction::Down));
key_bindings.insert(Keycode::S, GameCommand::MovePlayer(Direction::Down));
key_bindings.insert(Keycode::Left, GameCommand::MovePlayer(Direction::Left));
key_bindings.insert(Keycode::A, GameCommand::MovePlayer(Direction::Left));
key_bindings.insert(Keycode::Right, GameCommand::MovePlayer(Direction::Right));
key_bindings.insert(Keycode::D, GameCommand::MovePlayer(Direction::Right));
// Game actions
key_bindings.insert(Keycode::P, GameCommand::TogglePause);
key_bindings.insert(Keycode::Space, GameCommand::ToggleDebug);
key_bindings.insert(Keycode::M, GameCommand::MuteAudio);
key_bindings.insert(Keycode::R, GameCommand::ResetLevel);
key_bindings.insert(Keycode::Escape, GameCommand::Exit);
key_bindings.insert(Keycode::Q, GameCommand::Exit);
Self { key_bindings }
}
}
pub fn handle_input(bindings: Res<Bindings>, mut writer: EventWriter<GameEvent>, mut pump: NonSendMut<&'static mut EventPump>) {
for event in pump.poll_iter() {
match event {
Event::Quit { .. } => {
writer.write(GameEvent::Command(GameCommand::Exit));
}
Event::KeyDown { keycode: Some(key), .. } => {
let command = bindings.key_bindings.get(&key).copied();
if let Some(command) = command {
tracing::info!("triggering command: {:?}", command);
writer.write(GameEvent::Command(command));
}
}
_ => {}
}
}
}

2
src/lib.rs
View File

@@ -4,10 +4,12 @@ pub mod app;
pub mod asset;
pub mod audio;
pub mod constants;
pub mod ecs;
pub mod entity;
pub mod error;
pub mod game;
pub mod helpers;
pub mod input;
pub mod map;
pub mod platform;
pub mod texture;

2
src/main.rs
View File

@@ -10,10 +10,12 @@ mod asset;
mod audio;
mod constants;
mod ecs;
mod entity;
mod error;
mod game;
mod helpers;
mod input;
mod map;
mod platform;
mod texture;

80
src/map/builder.rs
View File

@@ -1,12 +1,13 @@
//! Map construction and building functionality.
use crate::constants::{MapTile, BOARD_CELL_SIZE, CELL_SIZE, RAW_BOARD};
use crate::ecs::NodeId;
use crate::entity::direction::Direction;
use crate::entity::graph::{EdgePermissions, Graph, Node, NodeId};
use crate::entity::item::{Item, ItemType};
use crate::entity::graph::{EdgePermissions, Graph, Node};
use crate::map::parser::MapTileParser;
use crate::map::render::MapRenderer;
use crate::texture::sprite::{AtlasTile, Sprite, SpriteAtlas};
use crate::texture::sprite::{Sprite, SpriteAtlas};
use bevy_ecs::resource::Resource;
use glam::{IVec2, Vec2};
use sdl2::render::{Canvas, RenderTarget};
use std::collections::{HashMap, VecDeque};
@@ -24,6 +25,7 @@ pub struct NodePositions {
}
/// The main map structure containing the game board and navigation graph.
#[derive(Resource)]
pub struct Map {
/// The node map for entity movement.
pub graph: Graph,
@@ -154,51 +156,43 @@ impl Map {
})
}
/// Renders the map to the given canvas.
///
/// This function draws the static map texture to the screen at the correct
/// position and scale.
pub fn render<T: RenderTarget>(&self, canvas: &mut Canvas<T>, atlas: &mut SpriteAtlas, map_tiles: &mut [AtlasTile]) {
MapRenderer::render_map(canvas, atlas, map_tiles);
}
/// Generates Item entities for pellets and energizers from the parsed map.
pub fn generate_items(&self, atlas: &SpriteAtlas) -> GameResult<Vec<Item>> {
// Pre-load sprites to avoid repeated texture lookups
let pellet_sprite = SpriteAtlas::get_tile(atlas, "maze/pellet.png")
.ok_or_else(|| MapError::InvalidConfig("Pellet texture not found".to_string()))?;
let energizer_sprite = SpriteAtlas::get_tile(atlas, "maze/energizer.png")
.ok_or_else(|| MapError::InvalidConfig("Energizer texture not found".to_string()))?;
// pub fn generate_items(&self, atlas: &SpriteAtlas) -> GameResult<Vec<Item>> {
// // Pre-load sprites to avoid repeated texture lookups
// let pellet_sprite = SpriteAtlas::get_tile(atlas, "maze/pellet.png")
// .ok_or_else(|| MapError::InvalidConfig("Pellet texture not found".to_string()))?;
// let energizer_sprite = SpriteAtlas::get_tile(atlas, "maze/energizer.png")
// .ok_or_else(|| MapError::InvalidConfig("Energizer texture not found".to_string()))?;
// Pre-allocate with estimated capacity (typical Pac-Man maps have ~240 pellets + 4 energizers)
let mut items = Vec::with_capacity(250);
// // Pre-allocate with estimated capacity (typical Pac-Man maps have ~240 pellets + 4 energizers)
// let mut items = Vec::with_capacity(250);
// Parse the raw board once
let parsed_map = MapTileParser::parse_board(RAW_BOARD)?;
let map = parsed_map.tiles;
// // Parse the raw board once
// let parsed_map = MapTileParser::parse_board(RAW_BOARD)?;
// let map = parsed_map.tiles;
// Iterate through the map and collect items more efficiently
for (x, row) in map.iter().enumerate() {
for (y, tile) in row.iter().enumerate() {
match tile {
MapTile::Pellet | MapTile::PowerPellet => {
let grid_pos = IVec2::new(x as i32, y as i32);
if let Some(&node_id) = self.grid_to_node.get(&grid_pos) {
let (item_type, sprite) = match tile {
MapTile::Pellet => (ItemType::Pellet, Sprite::new(pellet_sprite)),
MapTile::PowerPellet => (ItemType::Energizer, Sprite::new(energizer_sprite)),
_ => unreachable!(), // We already filtered for these types
};
items.push(Item::new(node_id, item_type, sprite));
}
}
_ => {}
}
}
}
// // Iterate through the map and collect items more efficiently
// for (x, row) in map.iter().enumerate() {
// for (y, tile) in row.iter().enumerate() {
// match tile {
// MapTile::Pellet | MapTile::PowerPellet => {
// let grid_pos = IVec2::new(x as i32, y as i32);
// if let Some(&node_id) = self.grid_to_node.get(&grid_pos) {
// let (item_type, sprite) = match tile {
// MapTile::Pellet => (ItemType::Pellet, Sprite::new(pellet_sprite)),
// MapTile::PowerPellet => (ItemType::Energizer, Sprite::new(energizer_sprite)),
// _ => unreachable!(), // We already filtered for these types
// };
// items.push(Item::new(node_id, item_type, sprite));
// }
// }
// _ => {}
// }
// }
// }
Ok(items)
}
// Ok(items)
// }
/// Renders a debug visualization with cursor-based highlighting.
///

3
src/map/mod.rs
View File

@@ -4,6 +4,3 @@ pub mod builder;
pub mod layout;
pub mod parser;
pub mod render;
// Re-export main types for convenience
pub use builder::Map;

9
src/platform/desktop.rs
View File

@@ -11,8 +11,12 @@ use crate::platform::Platform;
pub struct DesktopPlatform;
impl Platform for DesktopPlatform {
fn sleep(&self, duration: Duration) {
spin_sleep::sleep(duration);
fn sleep(&self, duration: Duration, focused: bool) {
if focused {
spin_sleep::sleep(duration);
} else {
std::thread::sleep(duration);
}
}
fn get_time(&self) -> f64 {
@@ -72,7 +76,6 @@ impl Platform for DesktopPlatform {
Asset::Wav3 => Ok(Cow::Borrowed(include_bytes!("../../assets/game/sound/waka/3.ogg"))),
Asset::Wav4 => Ok(Cow::Borrowed(include_bytes!("../../assets/game/sound/waka/4.ogg"))),
Asset::Atlas => Ok(Cow::Borrowed(include_bytes!("../../assets/game/atlas.png"))),
Asset::AtlasJson => Ok(Cow::Borrowed(include_bytes!("../../assets/game/atlas.json"))),
}
}
}

2
src/platform/emscripten.rs
View File

@@ -11,7 +11,7 @@ use crate::platform::Platform;
pub struct EmscriptenPlatform;
impl Platform for EmscriptenPlatform {
fn sleep(&self, duration: Duration) {
fn sleep(&self, duration: Duration, _focused: bool) {
unsafe {
emscripten_sleep(duration.as_millis() as u32);
}

2
src/platform/mod.rs
View File

@@ -11,7 +11,7 @@ pub mod emscripten;
/// Platform abstraction trait that defines cross-platform functionality.
pub trait Platform {
/// Sleep for the specified duration using platform-appropriate method.
fn sleep(&self, duration: Duration);
fn sleep(&self, duration: Duration, focused: bool);
/// Get the current time in seconds since some reference point.
/// This is available for future use in timing and performance monitoring.

1
src/texture/sprite.rs
View File

@@ -1,4 +1,5 @@
use anyhow::Result;
use bevy_ecs::resource::Resource;
use glam::U16Vec2;
use sdl2::pixels::Color;
use sdl2::rect::Rect;

10
tests/common/mod.rs
View File

@@ -2,7 +2,8 @@
use pacman::{
asset::{get_asset_bytes, Asset},
texture::sprite::SpriteAtlas,
game::state::ATLAS_FRAMES,
texture::sprite::{AtlasMapper, SpriteAtlas},
};
use sdl2::{
image::LoadTexture,
@@ -28,12 +29,13 @@ pub fn setup_sdl() -> Result<(Canvas<Window>, TextureCreator<WindowContext>, Sdl
pub fn create_atlas(canvas: &mut sdl2::render::Canvas<sdl2::video::Window>) -> SpriteAtlas {
let texture_creator = canvas.texture_creator();
let atlas_bytes = get_asset_bytes(Asset::Atlas).unwrap();
let atlas_json = get_asset_bytes(Asset::AtlasJson).unwrap();
let texture = texture_creator.load_texture_bytes(&atlas_bytes).unwrap();
let texture: Texture<'static> = unsafe { std::mem::transmute(texture) };
let mapper: pacman::texture::sprite::AtlasMapper = serde_json::from_slice(&atlas_json).unwrap();
let atlas_mapper = AtlasMapper {
frames: ATLAS_FRAMES.into_iter().map(|(k, v)| (k.to_string(), *v)).collect(),
};
SpriteAtlas::new(texture, mapper)
SpriteAtlas::new(texture, atlas_mapper)
}

2
tests/game.rs
View File

@@ -1,5 +1,5 @@
use pacman::constants::RAW_BOARD;
use pacman::map::Map;
use pacman::map::builder::Map;
mod collision;
mod item;

2
tests/map_builder.rs
View File

@@ -1,6 +1,6 @@
use glam::Vec2;
use pacman::constants::{CELL_SIZE, RAW_BOARD};
use pacman::map::Map;
use pacman::map::builder::Map;
use sdl2::render::Texture;
#[test]

34
tests/pacman.rs
View File

@@ -2,7 +2,6 @@ use pacman::entity::direction::Direction;
use pacman::entity::graph::{Graph, Node};
use pacman::entity::pacman::Pacman;
use pacman::texture::sprite::{AtlasMapper, MapperFrame, SpriteAtlas};
use sdl2::keyboard::Keycode;
use std::collections::HashMap;
fn create_test_graph() -> Graph {
@@ -72,36 +71,3 @@ fn test_pacman_creation() {
assert!(pacman.traverser.position.is_at_node());
assert_eq!(pacman.traverser.direction, Direction::Left);
}
#[test]
fn test_pacman_key_handling() {
let graph = create_test_graph();
let atlas = create_test_atlas();
let mut pacman = Pacman::new(&graph, 0, &atlas).unwrap();
let test_cases = [
(Keycode::Up, Direction::Up),
(Keycode::Down, Direction::Down),
(Keycode::Left, Direction::Left),
(Keycode::Right, Direction::Right),
];
for (key, expected_direction) in test_cases {
pacman.handle_key(key);
assert!(pacman.traverser.next_direction.is_some() || pacman.traverser.direction == expected_direction);
}
}
#[test]
fn test_pacman_invalid_key() {
let graph = create_test_graph();
let atlas = create_test_atlas();
let mut pacman = Pacman::new(&graph, 0, &atlas).unwrap();
let original_direction = pacman.traverser.direction;
let original_next_direction = pacman.traverser.next_direction;
pacman.handle_key(Keycode::Space);
assert_eq!(pacman.traverser.direction, original_direction);
assert_eq!(pacman.traverser.next_direction, original_next_direction);
}