Lunar

a 2D and 3D game engine built in Rust, designed around speed, portability, and a small, friendly public API.

what it is

2D and 3D. Both are first-class. The 2D path (lunar-2d / lunar-render) and the 3D path (lunar-3d / lunar-render-3d) share the same core, ECS, asset pipeline, and game loop. A game pulls in only the dimension it uses via feature flags.
Built for low-spec machines. Expensive work is front-loaded offline: BSP/PVS visibility, lightmap baking, LOD generation, texture compression, vertex quantization, SPIR-V precompilation. The runtime frame budget is spent only on visible geometry. Target: 60fps on a 2015 mid-range CPU.
One dependency for game code. Games depend on lunar and nothing else. Backends (windowing via SDL3, GPU via wgpu, ECS via bevy_ecs) are internal details, never named in a game's Cargo.toml. A compile-time test (tests/api_seal) enforces this.
Game code never needs unsafe. Inside the engine, unsafe is used sparingly and only where it is a genuine performance win (e.g. NEON pixel processing), with documented safety invariants.
Crossplatform and multiarch. The same game code runs on Linux, Windows, macOS, and the web (WebGPU + WASM). scripts/build_all.go cross-compiles 12 target triples.

non-goals

Audio — handled by Moonwalker, a separate project. Will return as a crate when mature. Not part of this workspace today.
Visual editor — a downstream project that will consume lunar, not part of this repo.

architecture

rendering decoupled from game logic — the engine renders Sprite / Text (2D) and Mesh3d / light / camera components (3D) automatically; immediate-mode helpers cover HUD and debug overlays
engine owns all memory — game code holds typed Handle<T> references; the engine evicts CPU-side mesh/texture data after GPU upload
fixed tick rate decoupled from frame cap — logic ticks at a fixed 30 / 60 / 120 / 240 Hz (accumulator-based, capped at 5 ticks/frame); rendering runs uncapped or at a chosen frame cap, with a render interpolation alpha for smooth sub-tick motion
parallel by default — non-conflicting ECS systems run concurrently on a thread pool (single-threaded fallback on WASM)
bevy_ecs under the hood — sealed behind lunar::prelude so game code never names it

crates

Game code depends only on lunar. The rest are internal or opt-in.

core

crate	purpose
`lunar`	public API facade — the one crate game code depends on
`lunar-core`	game loop, scheduler, plugin system, time, scene, hierarchy, save/load, pooling
`lunar-math`	math types (`Vec2/3/4`, `Mat2/3/4`, `Quat`, `Transform`, `Color`, `Rect`)
`lunar-input`	keyboard, mouse, gamepad, action maps (internal)
`lunar-macros`	derive macros (`Component`, `Resource`, `Event`, …) and the `texture!` macro

rendering

crate	purpose
`lunar-2d` / `lunar-render`	2D ECS components + wgpu sprite/text/camera/layer pipeline
`lunar-3d` / `lunar-render-3d`	3D scene components + clustered-forward PBR renderer (CSM, GTAO, SSR, STAA, FXAA, bloom, volumetric fog, contact shadows, decals, atmosphere)
`lunar-camera-3d`	spring-arm / orbit camera

asset pipeline

crate	purpose
`lunar-assets`	handle-based asset server, async loading, hot-reload, mip streaming
`lunar-image`	custom `.li` image format (LIF: planar + delta filter + zstd)
`lunar-atlas`	texture atlas packer
`lunar-gamedata` (+ `-build`)	baked binary game-data tables (zero runtime parsing)
`lunar-bsp` (+ `-build`)	BVH / BSP visibility, portal culling
`lunar-lightmap`	offline lightmap baker + runtime components

opt-in plugins (added to a game's Cargo.toml only when needed)

lunar-physics-2d, lunar-physics-3d, lunar-particles, lunar-pathfinding-rt, lunar-pathfinding-pre, lunar-ai, lunar-spline, lunar-timeline, lunar-animation, lunar-tilemap, lunar-dialogue, lunar-ui, lunar-zones, lunar-localization.

getting started

native

cargo run                              # smoke test (boots the engine, opens a window)
cargo run --features debug             # same, with ECS debug instrumentation
cargo run --example rpg_example        # RPG-style example
cargo run --example platform_demo      # 2D platformer
cargo run --example shooter_example    # top-down shooter

browser (WASM)

go run scripts/run_wasm.go shooter_example   # build for wasm, run wasm-bindgen, serve + open browser

requirements:

a browser with WebGPU support (Chrome 113+, recent Firefox/Safari with WebGPU enabled)
wasm-bindgen-cli on PATH
go 1.21+ (for the dev server in scripts/)

cross-compiling all targets

go run scripts/build_all.go --release           # all 12 triples (needs cargo-zigbuild)
go run scripts/build_all.go --target x86_64-unknown-linux-musl

targets

Linux (glibc and musl) — x86_64, aarch64, i686, armv7
Windows 10 / 11 — x86_64, i686 (gnu), aarch64 (gnullvm)
macOS — x86_64, aarch64
Web — WebGPU + WASM

minimal game

use lunar::prelude::*;

#[derive(Default)]
struct MyGame;

impl GamePlugin for MyGame {
    fn name(&self) -> &str { "MyGame" }
    fn build(&mut self, app: &mut App) {
        app.add_startup_system(spawn_player);
        app.add_system(move_player);
    }
}

fn spawn_player(mut commands: Commands, mut assets: ResMut<AssetServer>) {
    let texture = assets.load_texture("player.png");
    commands.spawn((
        Transform::from_xy(0.0, 0.0),
        Sprite::new(texture),
    ));
}

fn move_player(time: Res<Time>, input: Res<InputState>, mut query: Query<&mut Transform, With<Sprite>>) {
    for mut transform in &mut query {
        if input.is_key_held(KeyCode::Right) {
            transform.translation.x += 100.0 * time.delta_seconds();
        }
    }
}

lunar_app!(MyGame);

subsystems

input

fn jump(input: Res<InputState>) {
    if input.is_key_just_pressed(KeyCode::Space) {
        // jump!
    }
}

rendering

Game code spawns components; the engine renders them. The render system queries (Transform, Sprite) and (Transform, Text) each frame and submits draws automatically:

fn spawn_label(mut commands: Commands, mut assets: ResMut<AssetServer>) {
    let font = assets.load_font("ui.ttf");
    commands.spawn((
        Transform::from_xy(20.0, 35.0),
        Text::new("score: 42", font).with_size(16.0),
    ));
}

Immediate-mode helpers cover HUD overlays and debug primitives — useful when the thing you're drawing isn't a persistent entity:

fn hud_background(mut queue: ResMut<RenderQueue>) {
    queue.draw_rect(Vec2::new(10.0, 10.0), Vec2::new(200.0, 30.0), Color::BLACK);
}

Internals (DrawCommand, DrawKind, RenderQueue::push) are hidden — game code never constructs them.

assets

fn setup_assets(mut assets: ResMut<AssetServer>) {
    let texture = assets.load_texture("textures/player.png");
    if assets.is_texture_ready(&texture) {
        // ready to use
    }
}

plugins

struct MyPlugin;

impl GamePlugin for MyPlugin {
    fn name(&self) -> &str { "MyPlugin" }
    fn dependencies(&self) -> &[&str] { &["InputPlugin", "RenderPlugin"] }
    fn build(&mut self, app: &mut App) {
        app.insert_resource(MyResource::new());
        app.add_system(my_system);
    }
}

project structure

lunar/
├── crates/              # the engine — one crate per subsystem (see table above)
├── examples/            # rpg_example, platform_demo, shooter_example
├── tools/               # offline pipeline: texture compression, LOD gen, PVS bake, asset gen
├── scripts/             # build_all.go (multiarch), run_wasm.go (wasm dev server)
├── plans/               # design documents
├── tests/api_seal/      # compile-time guard that the prelude seal holds
└── src/
    ├── main.rs          # native smoke-test entry point
    └── web.rs           # WASM entry point

contributing

See CONTRIBUTING.md.

lunar-render 1.0.0