test: add more formatting tests

test: add tests for errors & events data structs
test: remove asset.rs tests, revamp constants tests
2025-12-07 11:15:47 -06:00 · 2025-08-17 23:47:47 -05:00 · 2025-08-17 23:46:23 -05:00 · 2025-08-17 23:45:42 -05:00 · 2025-08-17 23:29:43 -05:00 · 2025-08-16 15:25:34 -05:00
42 changed files with 706 additions and 1093 deletions
--- a/.pre-commit-config.yaml
+++ b/.pre-commit-config.yaml
@@ -20,3 +20,15 @@ repos:
        language: system
        types: [rust]
        pass_filenames: false
      - id: cargo-check
        name: cargo check
        entry: cargo check --all-targets
        language: system
        types_or: [rust, cargo, cargo-lock]
        pass_filenames: false
      - id: cargo-check-wasm
        name: cargo check for wasm32-unknown-emscripten
        entry: cargo check --all-targets --target=wasm32-unknown-emscripten
        language: system
        types_or: [rust, cargo, cargo-lock]
        pass_filenames: false
--- a/src/app.rs
+++ b/src/app.rs
@@ -12,6 +12,11 @@ use crate::constants::{CANVAS_SIZE, LOOP_TIME, SCALE};
 use crate::game::Game;
 use crate::platform::get_platform;
 /// Main application wrapper that manages SDL initialization, window lifecycle, and the game loop.
 ///
 /// Handles platform-specific setup, maintains consistent frame timing, and delegates
 /// game logic to the contained `Game` instance. The app manages focus state to
 /// optimize CPU usage when the window loses focus.
 pub struct App {
    pub game: Game,
    last_tick: Instant,
@@ -20,6 +25,16 @@ pub struct App {
 }
 impl App {
    /// Initializes SDL subsystems, creates the game window, and sets up the game state.
    ///
    /// Performs comprehensive initialization including video/audio subsystems, platform-specific
    /// console setup, window creation with proper scaling, and canvas configuration. All SDL
    /// resources are leaked to maintain 'static lifetimes required by the game architecture.
    ///
    /// # Errors
    ///
    /// Returns `GameError::Sdl` if any SDL initialization step fails, or propagates
    /// errors from `Game::new()` during game state setup.
    pub fn new() -> GameResult<Self> {
        let sdl_context: &'static Sdl = Box::leak(Box::new(sdl2::init().map_err(|e| GameError::Sdl(e.to_string()))?));
        let video_subsystem: &'static VideoSubsystem =
@@ -70,6 +85,16 @@ impl App {
        })
    }
    /// Executes a single frame of the game loop with consistent timing and optional sleep.
    ///
    /// Calculates delta time since the last frame, runs game logic via `game.tick()`,
    /// and implements frame rate limiting by sleeping for remaining time if the frame
    /// completed faster than the target `LOOP_TIME`. Sleep behavior varies based on
    /// window focus to conserve CPU when the game is not active.
    ///
    /// # Returns
    ///
    /// `true` if the game should continue running, `false` if the game requested exit.
    pub fn run(&mut self) -> bool {
        {
            let start = Instant::now();
--- a/src/asset.rs
+++ b/src/asset.rs
@@ -5,17 +5,28 @@
 use std::borrow::Cow;
 use strum_macros::EnumIter;
 /// Enumeration of all game assets with cross-platform loading support.
 ///
 /// Each variant corresponds to a specific file that can be loaded either from
 /// binary-embedded data or embedded filesystem (Emscripten).
 #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash, EnumIter)]
 pub enum Asset {
    Wav1,
    Wav2,
    Wav3,
    Wav4,
    /// Main sprite atlas containing all game graphics (atlas.png)
    AtlasImage,
    /// Terminal Vector font for text rendering (TerminalVector.ttf)
    Font,
 }
 impl Asset {
    /// Returns the relative file path for this asset within the game's asset directory.
    ///
    /// Paths are consistent across platforms and used by the Emscripten backend
    /// for filesystem loading. Desktop builds embed assets directly and don't
    /// use these paths at runtime.
    #[allow(dead_code)]
    pub fn path(&self) -> &str {
        use Asset::*;
@@ -35,7 +46,17 @@ mod imp {
    use crate::error::AssetError;
    use crate::platform::get_platform;
-    /// Returns the raw bytes of the given asset.
+    /// Loads asset bytes using the appropriate platform-specific method.
    ///
    /// On desktop platforms, returns embedded compile-time data via `include_bytes!`.
    /// On Emscripten, loads from the filesystem using the asset's path. The returned
    /// `Cow` allows zero-copy access to embedded data while supporting owned data
    /// when loaded from disk.
    ///
    /// # Errors
    ///
    /// Returns `AssetError::NotFound` if the asset file cannot be located (Emscripten only),
    /// or `AssetError::Io` for filesystem I/O failures.
    pub fn get_asset_bytes(asset: Asset) -> Result<Cow<'static, [u8]>, AssetError> {
        get_platform().get_asset_bytes(asset)
    }
--- a/src/audio.rs
+++ b/src/audio.rs
@@ -114,9 +114,11 @@ impl Audio {
        }
    }
-    /// Plays the "eat" sound effect.
+    /// Plays the next waka eating sound in the cycle of four variants.
    ///
-    /// If audio is disabled or muted, this function does nothing.
+    /// Automatically rotates through the four eating sound assets. The sound plays on channel 0 and the internal sound index
    /// advances to the next variant. Silently returns if audio is disabled, muted,
    /// or no sounds were loaded successfully.
    #[allow(dead_code)]
    pub fn eat(&mut self) {
        if self.disabled || self.muted || self.sounds.is_empty() {
@@ -136,9 +138,11 @@ impl Audio {
        self.next_sound_index = (self.next_sound_index + 1) % self.sounds.len();
    }
-    /// Instantly mute or unmute all channels.
+    /// Instantly mutes or unmutes all audio channels by adjusting their volume.
    ///
-    /// If audio is disabled, this function does nothing.
+    /// Sets all 4 mixer channels to zero volume when muting, or restores them to
    /// their default volume (32) when unmuting. The mute state is tracked internally
    /// regardless of whether audio is disabled, allowing the state to be preserved.
    pub fn set_mute(&mut self, mute: bool) {
        if !self.disabled {
            let channels = 4;
@@ -151,12 +155,19 @@ impl Audio {
        self.muted = mute;
    }
-    /// Returns `true` if the audio is muted.
+    /// Returns the current mute state regardless of whether audio is functional.
    ///
    /// This tracks the user's mute preference and will return `true` if muted
    /// even when the audio system is disabled due to initialization failures.
    pub fn is_muted(&self) -> bool {
        self.muted
    }
-    /// Returns `true` if the audio system is disabled.
+    /// Returns whether the audio system failed to initialize and is non-functional.
    ///
    /// Audio can be disabled due to SDL2_mixer initialization failures, missing
    /// audio device, or failure to load any sound assets. When disabled, all
    /// audio operations become no-ops.
    #[allow(dead_code)]
    pub fn is_disabled(&self) -> bool {
        self.disabled
--- a/src/constants.rs
+++ b/src/constants.rs
@@ -4,6 +4,11 @@ use std::time::Duration;
 use glam::UVec2;
 /// Target frame duration for 60 FPS game loop timing.
 ///
 /// Calculated as 1/60th of a second (≈16.67ms).
 ///
 /// Written out explicitly to satisfy const-eval constraints.
 pub const LOOP_TIME: Duration = Duration::from_nanos((1_000_000_000.0 / 60.0) as u64);
 /// The size of each cell, in pixels.
@@ -14,9 +19,16 @@ pub const BOARD_CELL_SIZE: UVec2 = UVec2::new(28, 31);
 /// The scale factor for the window (integer zoom)
 pub const SCALE: f32 = 2.6;
-/// The offset of the game board from the top-left corner of the window, in cells.
+/// Game board offset from window origin to reserve space for HUD elements.
 ///
 /// The 3-cell vertical offset (24 pixels) provides space at the top of the
 /// screen for score display, player lives, and other UI elements.
 pub const BOARD_CELL_OFFSET: UVec2 = UVec2::new(0, 3);
-/// The offset of the game board from the top-left corner of the window, in pixels.
+
 /// Pixel-space equivalent of `BOARD_CELL_OFFSET` for rendering calculations.
 ///
 /// Automatically calculated from the cell offset to maintain consistency
 /// when the cell size changes. Used for positioning sprites and debug overlays.
 pub const BOARD_PIXEL_OFFSET: UVec2 = UVec2::new(BOARD_CELL_OFFSET.x * CELL_SIZE, BOARD_CELL_OFFSET.y * CELL_SIZE);
 /// The size of the canvas, in pixels.
 pub const CANVAS_SIZE: UVec2 = UVec2::new(
@@ -24,22 +36,24 @@ pub const CANVAS_SIZE: UVec2 = UVec2::new(
    (BOARD_CELL_SIZE.y + BOARD_CELL_OFFSET.y) * CELL_SIZE,
 );
-/// An enum representing the different types of tiles on the map.
+/// Map tile types that define gameplay behavior and collision properties.
 #[derive(Debug, Clone, Copy, PartialEq)]
 pub enum MapTile {
-    /// An empty tile.
+    /// Traversable space with no collectible items
    Empty,
    /// A wall tile.
    Wall,
-    /// A regular pellet.
+    /// Small collectible. Implicitly a traversable tile.
    Pellet,
-    /// A power pellet.
+    /// Large collectible. Implicitly a traversable tile.
    PowerPellet,
-    /// A tunnel tile.
+    /// Special traversable tile that connects to tunnel portals.
    Tunnel,
 }
-/// The raw layout of the game board, as a 2D array of characters.
+/// ASCII art representation of the classic Pac-Man maze layout.
 ///
 /// Uses character symbols to define the game world. This layout is parsed by `MapTileParser`
 /// to generate the navigable graph and collision geometry.
 pub const RAW_BOARD: [&str; BOARD_CELL_SIZE.y as usize] = [
    "############################",
    "#............##............#",
--- a/src/entity/collision.rs
+++ b/src/entity/collision.rs
@@ -1,128 +0,0 @@
 // use smallvec::SmallVec;
 // use std::collections::HashMap;
 // 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;
 //     /// 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,
 // }
 // /// 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;
 //         self.entity_positions.insert(id, position);
 //         self.update_node_entities(id, position);
 //         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);
 //         }
 //         // 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);
 //         }
 //     }
 //     /// 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);
 //         for node in nodes {
 //             collisions.extend(self.entities_at_node(node));
 //         }
 //         // 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);
 //         }
 //     }
 //     /// 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);
 //     // 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
 // }
 // /// 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
 // }
--- a/src/entity/ghost.rs
+++ b/src/entity/ghost.rs
@@ -1,254 +0,0 @@
 // //! 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 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};
 // /// 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,
 // }
 // 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,
 //         }
 //     }
 // }
 // /// 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
 //     }
 //     fn traverser_mut(&mut self) -> &mut Traverser {
 //         &mut self.traverser
 //     }
 //     fn texture(&self) -> &DirectionalAnimatedTexture {
 //         &self.texture
 //     }
 //     fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture {
 //         &mut self.texture
 //     }
 //     fn speed(&self) -> f32 {
 //         self.speed
 //     }
 //     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);
 //         }
 //         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];
 //         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"
 //                             )))
 //                         })?,
 //                 ];
 //             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(),
 //         })
 //     }
 //     /// 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();
 //             // 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);
 //             }
 //         }
 //     }
 //     /// 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,
 //         );
 //         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
 //         }
 //     }
 // }
 // impl Collidable for Ghost {
 //     fn position(&self) -> crate::entity::traversal::Position {
 //         self.traverser.position
 //     }
 // }
--- a/src/entity/item.rs
+++ b/src/entity/item.rs
@@ -1,117 +0,0 @@
 // 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,
 //     },
 // }
 // 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,
 // }
 // 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 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,
 //         }
 //     }
 //     pub fn is_collected(&self) -> bool {
 //         self.collected
 //     }
 //     pub fn collect(&mut self) {
 //         self.collected = true;
 //     }
 //     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(());
 //         }
 //         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(())
 //     }
 // }
 // impl Collidable for Item {
 //     fn position(&self) -> crate::entity::traversal::Position {
 //         crate::entity::traversal::Position::AtNode(self.node_index)
 //     }
 // }
--- a/src/entity/mod.rs
+++ b/src/entity/mod.rs
@@ -1,7 +0,0 @@
 pub mod collision;
 pub mod direction;
 pub mod ghost;
 pub mod graph;
 pub mod item;
 pub mod pacman;
 pub mod r#trait;
--- a/src/entity/pacman.rs
+++ b/src/entity/pacman.rs
@@ -1,115 +0,0 @@
 // //! 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 tracing::error;
 // 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)
 // }
 // /// 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
 //     }
 //     fn traverser_mut(&mut self) -> &mut Traverser {
 //         &mut self.traverser
 //     }
 //     fn texture(&self) -> &DirectionalAnimatedTexture {
 //         &self.texture
 //     }
 //     fn texture_mut(&mut self) -> &mut DirectionalAnimatedTexture {
 //         &mut self.texture
 //     }
 //     fn speed(&self) -> f32 {
 //         1.125
 //     }
 //     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);
 //     }
 // }
 // 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())))?,
 //             ];
 //             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)?);
 //         }
 //         Ok(Self {
 //             traverser: Traverser::new(graph, start_node, Direction::Left, &can_pacman_traverse),
 //             texture: DirectionalAnimatedTexture::new(textures, stopped_textures),
 //         })
 //     }
 // }
 // impl Collidable for Pacman {
 //     fn position(&self) -> crate::entity::traversal::Position {
 //         self.traverser.position
 //     }
 // }
--- a/src/entity/trait.rs
+++ b/src/entity/trait.rs
@@ -1,114 +0,0 @@
 // //! 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 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;
 //     /// 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 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;
 //     /// 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);
 //     /// 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,
 //         ))
 //     }
 //     /// 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);
 //     }
 //     /// 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())))?;
 //         }
 //         Ok(())
 //     }
 // }
--- a/src/error.rs
+++ b/src/error.rs
@@ -31,9 +31,6 @@ pub enum GameError {
    #[error("Entity error: {0}")]
    Entity(#[from] EntityError),
    #[error("Game state error: {0}")]
    GameState(#[from] GameStateError),
    #[error("SDL error: {0}")]
    Sdl(String),
@@ -51,6 +48,8 @@ pub enum GameError {
 pub enum AssetError {
    #[error("IO error: {0}")]
    Io(#[from] io::Error),
    #[allow(dead_code)]
    #[error("Asset not found: {0}")]
    NotFound(String),
 }
@@ -109,18 +108,8 @@ pub enum EntityError {
    #[error("Edge not found: from {from} to {to}")]
    EdgeNotFound { from: usize, to: usize },
    #[error("Invalid movement: {0}")]
    InvalidMovement(String),
    #[error("Pathfinding failed: {0}")]
    PathfindingFailed(String),
 }
 /// Errors related to game state operations.
 #[derive(thiserror::Error, Debug)]
 pub enum GameStateError {}
 /// Errors related to map operations.
 #[derive(thiserror::Error, Debug)]
 pub enum MapError {
--- a/src/events.rs
+++ b/src/events.rs
@@ -1,18 +1,37 @@
-use bevy_ecs::prelude::*;
+use bevy_ecs::{entity::Entity, event::Event};
 use crate::map::direction::Direction;
 /// Player input commands that trigger specific game actions.
 ///
 /// Commands are generated by the input system in response to keyboard events
 /// and processed by appropriate game systems to modify state or behavior.
 #[derive(Clone, Copy, Debug, PartialEq, Eq)]
 pub enum GameCommand {
    /// Request immediate game shutdown
    Exit,
-    MovePlayer(crate::entity::direction::Direction),
+    /// Set Pac-Man's movement direction
    MovePlayer(Direction),
    /// Cycle through debug visualization modes
    ToggleDebug,
    /// Toggle audio mute state
    MuteAudio,
    /// Restart the current level with fresh entity positions and items
    ResetLevel,
    /// Pause or resume game ticking logic
    TogglePause,
 }
 /// Global events that flow through the ECS event system to coordinate game behavior.
 ///
 /// Events enable loose coupling between systems - input generates commands, collision
 /// detection reports overlaps, and various systems respond appropriately without
 /// direct dependencies.
 #[derive(Event, Clone, Copy, Debug, PartialEq, Eq)]
 pub enum GameEvent {
    /// Player input command to be processed by relevant game systems
    Command(GameCommand),
    /// Physical overlap detected between two entities requiring gameplay response
    Collision(Entity, Entity),
 }
--- a/src/game/mod.rs
+++ b/src/game/mod.rs
@@ -3,10 +3,10 @@
 include!(concat!(env!("OUT_DIR"), "/atlas_data.rs"));
 use crate::constants::CANVAS_SIZE;
 use crate::entity::direction::Direction;
 use crate::error::{GameError, GameResult, TextureError};
 use crate::events::GameEvent;
 use crate::map::builder::Map;
 use crate::map::direction::Direction;
 use crate::systems::blinking::Blinking;
 use crate::systems::movement::{BufferedDirection, Position, Velocity};
 use crate::systems::player::player_movement_system;
@@ -48,18 +48,37 @@ use crate::{
    texture::sprite::{AtlasMapper, SpriteAtlas},
 };
-pub mod state;
+/// Core game state manager built on the Bevy ECS architecture.
 /// The `Game` struct is the main entry point for the game.
 ///
-/// It contains the game's state and logic, and is responsible for
+/// Orchestrates all game systems through a centralized `World` containing entities,
-/// handling user input, updating the game state, and rendering the game.
+/// components, and resources, while a `Schedule` defines system execution order.
 /// Handles initialization of graphics resources, entity spawning, and per-frame
 /// game logic coordination. SDL2 resources are stored as `NonSend` to respect
 /// thread safety requirements while integrating with the ECS.
 pub struct Game {
    pub world: World,
    pub schedule: Schedule,
 }
 impl Game {
    /// Initializes the complete game state including ECS world, graphics, and entity spawning.
    ///
    /// Performs extensive setup: creates render targets and debug textures, loads and parses
    /// the sprite atlas, renders the static map to a cached texture, builds the navigation
    /// graph from the board layout, spawns Pac-Man with directional animations, creates
    /// all four ghosts with their AI behavior, and places collectible items throughout
    /// the maze. Registers event types and configures the system execution schedule.
    ///
    /// # Arguments
    ///
    /// * `canvas` - SDL2 rendering context with static lifetime for ECS storage
    /// * `texture_creator` - SDL2 texture factory for creating render targets
    /// * `event_pump` - SDL2 event polling interface for input handling
    ///
    /// # Errors
    ///
    /// Returns `GameError` for SDL2 failures, asset loading problems, atlas parsing
    /// errors, or entity initialization issues.
    pub fn new(
        canvas: &'static mut Canvas<Window>,
        texture_creator: &'static mut TextureCreator<WindowContext>,
@@ -291,7 +310,12 @@ impl Game {
        Ok(Game { world, schedule })
    }
-    /// Spowns all four ghosts at their starting positions with appropriate textures.
+    /// Creates and spawns all four ghosts with unique AI personalities and directional animations.
    ///
    /// # Errors
    ///
    /// Returns `GameError::Texture` if any ghost sprite cannot be found in the atlas,
    /// typically indicating missing or misnamed sprite files.
    fn spawn_ghosts(world: &mut World) -> GameResult<()> {
        // Extract the data we need first to avoid borrow conflicts
        let ghost_start_positions = {
@@ -396,9 +420,21 @@ impl Game {
        Ok(())
    }
-    /// Ticks the game state.
+    /// Executes one frame of game logic by running all scheduled ECS systems.
    ///
-    /// Returns true if the game should exit.
+    /// Updates the world's delta time resource and runs the complete system pipeline:
    /// input processing, entity movement, collision detection, item collection,
    /// audio playback, animation updates, and rendering. Each system operates on
    /// relevant entities and modifies world state, with the schedule ensuring
    /// proper execution order and data dependencies.
    ///
    /// # Arguments
    ///
    /// * `dt` - Frame delta time in seconds for time-based animations and movement
    ///
    /// # Returns
    ///
    /// `true` if the game should terminate (exit command received), `false` to continue
    pub fn tick(&mut self, dt: f32) -> bool {
        self.world.insert_resource(DeltaTime(dt));
--- a/src/game/state.rs
+++ b/src/game/state.rs
@@ -1,153 +0,0 @@
 // use std::collections::VecDeque;
 // use sdl2::{
 //     image::LoadTexture,
 //     render::{Texture, TextureCreator},
 //     video::WindowContext,
 // };
 // use smallvec::SmallVec;
 // 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,
 //     },
 // };
 // include!(concat!(env!("OUT_DIR"), "/atlas_data.rs"));
 // /// 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,
 //     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>,
 //     // Collision system
 //     pub(crate) collision_system: CollisionSystem,
 //     // Rendering resources
 //     pub(crate) atlas: SpriteAtlas,
 //     pub(crate) text_texture: TextTexture,
 //     // Audio
 //     pub audio: Audio,
 //     // Map texture pre-rendering
 //     pub(crate) map_texture: Option<Texture<'static>>,
 //     pub(crate) map_rendered: bool,
 //     pub(crate) texture_creator: &'static TextureCreator<WindowContext>,
 // }
 // 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)?;
 //         let start_node = map.start_positions.pacman;
 //         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_mapper = AtlasMapper {
 //             frames: ATLAS_FRAMES.into_iter().map(|(k, v)| (k.to_string(), *v)).collect(),
 //         };
 //         let atlas = SpriteAtlas::new(atlas_texture, atlas_mapper);
 //         let text_texture = TextTexture::new(1.0);
 //         let audio = Audio::new();
 //         let pacman = Pacman::new(&map.graph, start_node, &atlas)?;
 //         // Generate items (pellets and energizers)
 //         let items = map.generate_items(&atlas)?;
 //         // Initialize collision system
 //         let mut collision_system = CollisionSystem::default();
 //         // 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(),
 //         })
 //     }
 // }
--- a/src/helpers.rs
+++ b/src/helpers.rs
@@ -1,10 +0,0 @@
 use glam::{IVec2, UVec2};
 use sdl2::rect::Rect;
 pub fn centered_with_size(pixel_pos: IVec2, size: UVec2) -> Rect {
    // Ensure the position doesn't cause integer overflow when centering
    let x = pixel_pos.x.saturating_sub(size.x as i32 / 2);
    let y = pixel_pos.y.saturating_sub(size.y as i32 / 2);
    Rect::new(x, y, size.x, size.y)
 }
--- a/src/lib.rs
+++ b/src/lib.rs
@@ -4,11 +4,9 @@ pub mod app;
 pub mod asset;
 pub mod audio;
 pub mod constants;
 pub mod entity;
 pub mod error;
 pub mod events;
 pub mod game;
 pub mod helpers;
 pub mod map;
 pub mod platform;
 pub mod systems;
--- a/src/main.rs
+++ b/src/main.rs
@@ -10,11 +10,9 @@ mod asset;
 mod audio;
 mod constants;
 mod entity;
 mod error;
 mod events;
 mod game;
 mod helpers;
 mod map;
 mod platform;
 mod systems;
--- a/src/map/builder.rs
+++ b/src/map/builder.rs
@@ -1,7 +1,7 @@
 //! Map construction and building functionality.
 use crate::constants::{MapTile, BOARD_CELL_SIZE, CELL_SIZE};
-use crate::entity::direction::Direction;
+use crate::map::direction::Direction;
-use crate::entity::graph::{Graph, Node, TraversalFlags};
+use crate::map::graph::{Graph, Node, TraversalFlags};
 use crate::map::parser::MapTileParser;
 use crate::systems::movement::NodeId;
 use bevy_ecs::resource::Resource;
@@ -11,25 +11,37 @@ use tracing::debug;
 use crate::error::{GameResult, MapError};
-/// The starting positions of the entities in the game.
+/// Predefined spawn locations for all game entities within the navigation graph.
 ///
 /// These positions are determined during map parsing and graph construction.
 pub struct NodePositions {
    /// Pac-Man's starting position in the lower section of the maze
    pub pacman: NodeId,
    /// Blinky starts at the ghost house entrance
    pub blinky: NodeId,
    /// Pinky starts in the left area of the ghost house
    pub pinky: NodeId,
    /// Inky starts in the right area of the ghost house
    pub inky: NodeId,
    /// Clyde starts in the center of the ghost house
    pub clyde: NodeId,
 }
-/// The main map structure containing the game board and navigation graph.
+/// Complete maze representation combining visual layout with navigation pathfinding.
 ///
 /// Transforms the ASCII board layout into a fully connected navigation graph
 /// while preserving tile-based collision and rendering data. The graph enables
 /// smooth entity movement with proper pathfinding, while the grid mapping allows
 /// efficient spatial queries and debug visualization.
 #[derive(Resource)]
 pub struct Map {
-    /// The node map for entity movement.
+    /// Connected graph of navigable positions.
    pub graph: Graph,
-    /// A mapping from grid positions to node IDs.
+    /// Bidirectional mapping between 2D grid coordinates and graph node indices.
    pub grid_to_node: HashMap<IVec2, NodeId>,
-    /// A mapping of the starting positions of the entities.
+    /// Predetermined spawn locations for all game entities
    pub start_positions: NodePositions,
-    /// The raw tile data for the map.
+    /// 2D array of tile types for collision detection and rendering
    tiles: [[MapTile; BOARD_CELL_SIZE.y as usize]; BOARD_CELL_SIZE.x as usize],
 }
@@ -162,7 +174,18 @@ impl Map {
        })
    }
-    /// Builds the house structure in the graph.
+    /// Constructs the ghost house area with restricted access and internal navigation.
    ///
    /// Creates a multi-level ghost house with entrance control, internal movement
    /// areas, and starting positions for each ghost. The house entrance uses
    /// ghost-only traversal flags to prevent Pac-Man from entering while allowing
    /// ghosts to exit. Internal nodes are arranged in vertical lines to provide
    /// distinct starting areas for each ghost character.
    ///
    /// # Returns
    ///
    /// Tuple of node IDs: (house_entrance, left_center, center_center, right_center)
    /// representing the four key positions within the ghost house structure.
    fn build_house(
        graph: &mut Graph,
        grid_to_node: &HashMap<IVec2, NodeId>,
@@ -296,7 +319,10 @@ impl Map {
        ))
    }
-    /// Builds the tunnel connections in the graph.
+    /// Creates horizontal tunnel portals for instant teleportation across the maze.
    ///
    /// Establishes the tunnel system that allows entities to instantly travel from the left edge of the maze to the right edge.
    /// Creates hidden intermediate nodes beyond the visible tunnel entrances and connects them with zero-distance edges for instantaneous traversal.
    fn build_tunnels(
        graph: &mut Graph,
        grid_to_node: &HashMap<IVec2, NodeId>,
--- a/src/entity/direction.rs
+++ b/src/entity/direction.rs
--- a/src/entity/graph.rs
+++ b/src/entity/graph.rs
--- a/src/map/mod.rs
+++ b/src/map/mod.rs
@@ -1,6 +1,8 @@
 //! This module defines the game map and provides functions for interacting with it.
 pub mod builder;
 pub mod direction;
 pub mod graph;
 pub mod layout;
 pub mod parser;
 pub mod render;
--- a/src/map/parser.rs
+++ b/src/map/parser.rs
@@ -4,16 +4,21 @@ use crate::constants::{MapTile, BOARD_CELL_SIZE};
 use crate::error::ParseError;
 use glam::IVec2;
-/// Represents the parsed data from a raw board layout.
+/// Structured representation of parsed ASCII board layout with extracted special positions.
 ///
 /// Contains the complete board state after character-to-tile conversion, along with
 /// the locations of special gameplay elements that require additional processing
 /// during graph construction. Special positions are extracted during parsing to
 /// enable proper map builder initialization.
 #[derive(Debug)]
 pub struct ParsedMap {
-    /// The parsed tile layout.
+    /// 2D array of tiles converted from ASCII characters
    pub tiles: [[MapTile; BOARD_CELL_SIZE.y as usize]; BOARD_CELL_SIZE.x as usize],
-    /// The positions of the house door tiles.
+    /// Two positions marking the ghost house entrance (represented by '=' characters)
    pub house_door: [Option<IVec2>; 2],
-    /// The positions of the tunnel end tiles.
+    /// Two positions marking tunnel portals for wraparound teleportation ('T' characters)
    pub tunnel_ends: [Option<IVec2>; 2],
-    /// Pac-Man's starting position.
+    /// Starting position for Pac-Man (marked by 'X' character in the layout)
    pub pacman_start: Option<IVec2>,
 }
@@ -21,15 +26,18 @@ pub struct ParsedMap {
 pub struct MapTileParser;
 impl MapTileParser {
-    /// Parses a single character into a map tile.
+    /// Converts ASCII characters from the board layout into corresponding tile types.
    ///
-    /// # Arguments
+    /// Interprets the character-based maze representation: walls (`#`), collectible
    /// pellets (`.` and `o`), traversable spaces (` `), tunnel entrances (`T`),
    /// ghost house doors (`=`), and entity spawn markers (`X`). Special characters
    /// that don't represent tiles in the final map (like spawn markers) are
    /// converted to `Empty` tiles while their positions are tracked separately.
    ///
-    /// * `c` - The character to parse
+    /// # Errors
    ///
-    /// # Returns
+    /// Returns `ParseError::UnknownCharacter` for any character not defined
-    ///
+    /// in the game's ASCII art vocabulary.
    /// The parsed map tile, or an error if the character is unknown.
    pub fn parse_character(c: char) -> Result<MapTile, ParseError> {
        match c {
            '#' => Ok(MapTile::Wall),
--- a/src/platform/mod.rs
+++ b/src/platform/mod.rs
@@ -10,29 +10,29 @@ mod desktop;
 #[cfg(target_os = "emscripten")]
 mod emscripten;
-/// Platform abstraction trait that defines cross-platform functionality.
+/// Cross-platform abstraction layer providing unified APIs for platform-specific operations.
 pub trait CommonPlatform {
-    /// Sleep for the specified duration using platform-appropriate method.
+    /// Platform-specific sleep function (required due to Emscripten's non-standard sleep requirements).
    ///
    /// Provides access to current window focus state, useful for changing sleep algorithm conditionally.
    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.
    #[allow(dead_code)]
    fn get_time(&self) -> f64;
-    /// Initialize platform-specific console functionality.
+    /// Configures platform-specific console and debugging output capabilities.
    fn init_console(&self) -> Result<(), PlatformError>;
-    /// Get canvas size for platforms that need it (e.g., Emscripten).
+    /// Retrieves the actual display canvas dimensions.
    /// This is available for future use in responsive design.
    #[allow(dead_code)]
    fn get_canvas_size(&self) -> Option<(u32, u32)>;
-    /// Load asset bytes using platform-appropriate method.
+    /// Loads raw asset data using the appropriate platform-specific method.
    fn get_asset_bytes(&self, asset: Asset) -> Result<Cow<'static, [u8]>, AssetError>;
 }
-/// Get the current platform implementation.
+/// Returns the appropriate platform implementation based on compile-time target.
 #[allow(dead_code)]
 pub fn get_platform() -> &'static dyn CommonPlatform {
    #[cfg(not(target_os = "emscripten"))]
--- a/src/systems/collision.rs
+++ b/src/systems/collision.rs
@@ -9,6 +9,13 @@ use crate::map::builder::Map;
 use crate::systems::components::{Collider, ItemCollider, PacmanCollider};
 use crate::systems::movement::Position;
 /// Detects overlapping entities and generates collision events for gameplay systems.
 ///
 /// Performs distance-based collision detection between Pac-Man and collectible items
 /// using each entity's position and collision radius. When entities overlap, emits
 /// a `GameEvent::Collision` for the item system to handle scoring and removal.
 /// Collision detection accounts for both entities being in motion and supports
 /// circular collision boundaries for accurate gameplay feel.
 pub fn collision_system(
    map: Res<Map>,
    pacman_query: Query<(Entity, &Position, &Collider), With<PacmanCollider>>,
--- a/src/systems/components.rs
+++ b/src/systems/components.rs
@@ -2,7 +2,7 @@ use bevy_ecs::{bundle::Bundle, component::Component, resource::Resource};
 use bitflags::bitflags;
 use crate::{
-    entity::graph::TraversalFlags,
+    map::graph::TraversalFlags,
    systems::movement::{BufferedDirection, Position, Velocity},
    texture::{animated::AnimatedTexture, sprite::AtlasTile},
 };
@@ -41,6 +41,7 @@ impl Ghost {
    }
    /// Returns the ghost's color for debug rendering.
    #[allow(dead_code)]
    pub fn debug_color(&self) -> sdl2::pixels::Color {
        match self {
            Ghost::Blinky => sdl2::pixels::Color::RGB(255, 0, 0),    // Red
--- a/src/systems/ghost.rs
+++ b/src/systems/ghost.rs
@@ -3,18 +3,18 @@ use rand::prelude::*;
 use smallvec::SmallVec;
 use crate::{
-    entity::{direction::Direction, graph::Edge},
+    map::{
-    map::builder::Map,
+        builder::Map,
        direction::Direction,
        graph::{Edge, TraversalFlags},
    },
    systems::{
        components::{DeltaTime, Ghost},
        movement::{Position, Velocity},
    },
 };
-/// Ghost AI system that handles randomized movement decisions.
+/// Autonomous ghost AI system implementing randomized movement with backtracking avoidance.
 ///
 /// This system runs on all ghosts and makes periodic decisions about
 /// which direction to move in when they reach intersections.
 pub fn ghost_movement_system(
    map: Res<Map>,
    delta_time: Res<DeltaTime>,
@@ -32,9 +32,7 @@ pub fn ghost_movement_system(
                    // Collect all available directions that ghosts can traverse
                    for edge in Direction::DIRECTIONS.iter().flat_map(|d| intersection.get(*d)) {
-                        if edge.traversal_flags.contains(crate::entity::graph::TraversalFlags::GHOST)
+                        if edge.traversal_flags.contains(TraversalFlags::GHOST) && edge.direction != opposite {
                            && edge.direction != opposite
                        {
                            non_opposite_options.push(edge);
                        }
                    }
--- a/src/systems/input.rs
+++ b/src/systems/input.rs
@@ -10,8 +10,8 @@ use sdl2::{event::Event, keyboard::Keycode, EventPump};
 use crate::systems::components::DeltaTime;
 use crate::{
    entity::direction::Direction,
    events::{GameCommand, GameEvent},
    map::direction::Direction,
 };
 #[derive(Resource, Default, Debug, Copy, Clone)]
--- a/src/systems/movement.rs
+++ b/src/systems/movement.rs
@@ -1,10 +1,13 @@
 use crate::entity::direction::Direction;
 use crate::entity::graph::Graph;
 use crate::error::{EntityError, GameResult};
 use crate::map::direction::Direction;
 use crate::map::graph::Graph;
 use bevy_ecs::component::Component;
 use glam::Vec2;
-/// A unique identifier for a node, represented by its index in the graph's storage.
+/// Zero-based index identifying a specific node in the navigation graph.
 ///
 /// Nodes represent discrete movement targets in the maze. The index directly corresponds to the node's position in the
 /// graph's internal storage arrays.
 pub type NodeId = usize;
 /// A component that represents the speed and cardinal direction of an entity.
@@ -24,15 +27,19 @@ pub enum BufferedDirection {
    Some { direction: Direction, remaining_time: f32 },
 }
-/// Pure spatial position component - works for both static and dynamic entities.
+/// Entity position state that handles both stationary entities and moving entities.
 ///
 /// Supports precise positioning during movement between discrete navigation nodes.
 /// When moving, entities smoothly interpolate along edges while tracking exact distance remaining to the target node.
 #[derive(Component, Debug, Copy, Clone, PartialEq)]
 pub enum Position {
-    Stopped {
+    /// Entity is stationary at a specific graph node.
-        node: NodeId,
+    Stopped { node: NodeId },
-    },
+    /// Entity is traveling between two nodes.
    Moving {
        from: NodeId,
        to: NodeId,
        /// Distance remaining to reach the target node.
        remaining_distance: f32,
    },
 }
@@ -82,9 +89,21 @@ impl Position {
        ))
    }
-    /// Moves the position by a given distance towards it's current target node.
+    /// Advances movement progress by the specified distance with overflow handling.
    ///
-    /// Returns the overflow distance, if any.
+    /// For moving entities, decreases the remaining distance to the target node.
    /// If the distance would overshoot the target, the entity transitions to
    /// `Stopped` state and returns the excess distance for chaining movement
    /// to the next edge in the same frame.
    ///
    /// # Arguments
    ///
    /// * `distance` - Distance to travel this frame (typically speed × delta_time)
    ///
    /// # Returns
    ///
    /// `Some(overflow)` if the target was reached with distance remaining,
    /// `None` if still moving or already stopped.
    pub fn tick(&mut self, distance: f32) -> Option<f32> {
        if distance <= 0.0 || self.is_at_node() {
            return None;
--- a/src/systems/player.rs
+++ b/src/systems/player.rs
@@ -6,10 +6,10 @@ use bevy_ecs::{
 };
 use crate::{
    entity::graph::Edge,
    error::GameError,
    events::{GameCommand, GameEvent},
    map::builder::Map,
    map::graph::Edge,
    systems::{
        components::{AudioState, DeltaTime, EntityType, GlobalState, PlayerControlled},
        debug::DebugState,
@@ -17,7 +17,12 @@ use crate::{
    },
 };
-// Handles player input and control
+/// Processes player input commands and updates game state accordingly.
 ///
 /// Handles keyboard-driven commands like movement direction changes, debug mode
 /// toggling, audio muting, and game exit requests. Movement commands are buffered
 /// to allow direction changes before reaching intersections, improving gameplay
 /// responsiveness. Non-movement commands immediately modify global game state.
 pub fn player_control_system(
    mut events: EventReader<GameEvent>,
    mut state: ResMut<GlobalState>,
@@ -69,6 +74,11 @@ fn can_traverse(entity_type: EntityType, edge: Edge) -> bool {
    edge.traversal_flags.contains(entity_flags)
 }
 /// Executes frame-by-frame movement for Pac-Man.
 ///
 /// Handles movement logic including buffered direction changes, edge traversal validation, and continuous movement between nodes.
 /// When stopped, prioritizes buffered directions for responsive controls, falling back to current direction.
 /// Supports movement chaining within a single frame when traveling at high speeds.
 pub fn player_movement_system(
    map: Res<Map>,
    delta_time: Res<DeltaTime>,
--- a/src/systems/render.rs
+++ b/src/systems/render.rs
@@ -7,6 +7,7 @@ use bevy_ecs::entity::Entity;
 use bevy_ecs::event::EventWriter;
 use bevy_ecs::prelude::{Changed, Or, RemovedComponents};
 use bevy_ecs::system::{NonSendMut, Query, Res, ResMut};
 use sdl2::rect::{Point, Rect};
 use sdl2::render::{Canvas, Texture};
 use sdl2::video::Window;
@@ -99,9 +100,10 @@ pub fn render_system(
                let pos = position.get_pixel_position(&map.graph);
                match pos {
                    Ok(pos) => {
-                        let dest = crate::helpers::centered_with_size(
+                        let dest = Rect::from_center(
-                            glam::IVec2::new(pos.x as i32, pos.y as i32),
+                            Point::from((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.size.x as u32,
                            renderable.sprite.size.y as u32,
                        );
                        renderable
--- a/src/texture/animated.rs
+++ b/src/texture/animated.rs
@@ -1,11 +1,19 @@
 use crate::error::{AnimatedTextureError, GameError, GameResult, TextureError};
 use crate::texture::sprite::AtlasTile;
 /// Frame-based animation system for cycling through multiple sprite tiles.
 ///
 /// Manages automatic frame progression based on elapsed time.
 /// Uses a time banking system to ensure consistent animation speed regardless of frame rate variations.
 #[derive(Debug, Clone)]
 pub struct AnimatedTexture {
    /// Sequence of sprite tiles that make up the animation frames
    tiles: Vec<AtlasTile>,
    /// Duration each frame should be displayed (in seconds)
    frame_duration: f32,
    /// Index of the currently active frame in the tiles vector
    current_frame: usize,
    /// Accumulated time since the last frame change (for smooth timing)
    time_bank: f32,
 }
@@ -25,6 +33,16 @@ impl AnimatedTexture {
        })
    }
    /// Advances the animation by the specified time delta with automatic frame cycling.
    ///
    /// Accumulates time in the time bank and progresses through frames when enough
    /// time has elapsed. Supports frame rates independent of game frame rate by
    /// potentially advancing multiple frames in a single call if `dt` is large.
    /// Animation loops automatically when reaching the final frame.
    ///
    /// # Arguments
    ///
    /// * `dt` - Time elapsed since the last tick (typically frame delta time)
    pub fn tick(&mut self, dt: f32) {
        self.time_bank += dt;
        while self.time_bank >= self.frame_duration {
--- a/src/texture/sprite.rs
+++ b/src/texture/sprite.rs
@@ -8,8 +8,10 @@ use std::collections::HashMap;
 use crate::error::TextureError;
 /// Atlas frame mapping data loaded from JSON metadata files.
 #[derive(Clone, Debug, Deserialize)]
 pub struct AtlasMapper {
    /// Mapping from sprite name to frame bounds within the atlas texture
    pub frames: HashMap<String, MapperFrame>,
 }
@@ -72,10 +74,19 @@ impl AtlasTile {
    }
 }
 /// High-performance sprite atlas providing fast texture region lookups and rendering.
 ///
 /// Combines a single large texture with metadata mapping to enable efficient
 /// sprite rendering without texture switching. Caches color modulation state
 /// to minimize redundant SDL2 calls and supports both named sprite lookups
 /// and optional default color modulation configuration.
 pub struct SpriteAtlas {
    /// The combined texture containing all sprite frames
    texture: Texture<'static>,
    /// Mapping from sprite names to their pixel coordinates within the texture
    tiles: HashMap<String, MapperFrame>,
    default_color: Option<Color>,
    /// Cached color modulation state to avoid redundant SDL2 calls
    last_modulation: Option<Color>,
 }
@@ -89,6 +100,12 @@ impl SpriteAtlas {
        }
    }
    /// Retrieves a sprite tile by name from the atlas with fast HashMap lookup.
    ///
    /// Returns an `AtlasTile` containing the texture coordinates and dimensions
    /// for the named sprite, or `None` if the sprite name is not found in the
    /// atlas. The returned tile can be used for immediate rendering or stored
    /// for repeated use in animations and entity sprites.
    pub fn get_tile(&self, name: &str) -> Option<AtlasTile> {
        self.tiles.get(name).map(|frame| AtlasTile {
            pos: U16Vec2::new(frame.x, frame.y),
--- a/tests/asset.rs
+++ b/tests/asset.rs
@@ -1,14 +0,0 @@
 use pacman::asset::Asset;
 use std::path::Path;
 use strum::IntoEnumIterator;
 #[test]
 fn test_asset_paths_valid() {
    let base_path = Path::new("assets/game/");
    for asset in Asset::iter() {
        let path = base_path.join(asset.path());
        assert!(path.exists(), "Asset path does not exist: {:?}", path);
        assert!(path.is_file(), "Asset path is not a file: {:?}", path);
    }
 }
--- a/tests/constants.rs
+++ b/tests/constants.rs
@@ -2,27 +2,34 @@ use pacman::constants::*;
 #[test]
 fn test_raw_board_structure() {
    // Test board dimensions match expected size
    assert_eq!(RAW_BOARD.len(), BOARD_CELL_SIZE.y as usize);
    for row in RAW_BOARD.iter() {
        assert_eq!(row.len(), BOARD_CELL_SIZE.x as usize);
    }
-    // Test boundaries
+    // Test boundaries are properly walled
    assert!(RAW_BOARD[0].chars().all(|c| c == '#'));
    assert!(RAW_BOARD[RAW_BOARD.len() - 1].chars().all(|c| c == '#'));
    // Test tunnel row
    let tunnel_row = RAW_BOARD[14];
    assert_eq!(tunnel_row.chars().next().unwrap(), 'T');
    assert_eq!(tunnel_row.chars().last().unwrap(), 'T');
 }
 #[test]
-fn test_raw_board_content() {
+fn test_raw_board_contains_required_elements() {
-    let power_pellet_count = RAW_BOARD.iter().flat_map(|row| row.chars()).filter(|&c| c == 'o').count();
+    // Test that essential game elements are present
-    assert_eq!(power_pellet_count, 4);
+    assert!(
-
+        RAW_BOARD.iter().any(|row| row.contains('X')),
-    assert!(RAW_BOARD.iter().any(|row| row.contains('X')));
+        "Board should contain Pac-Man start position"
-    assert!(RAW_BOARD.iter().any(|row| row.contains("==")));
+    );
    assert!(
        RAW_BOARD.iter().any(|row| row.contains("==")),
        "Board should contain ghost house door"
    );
    assert!(
        RAW_BOARD.iter().any(|row| row.chars().any(|c| c == 'T')),
        "Board should contain tunnel entrances"
    );
    assert!(
        RAW_BOARD.iter().any(|row| row.chars().any(|c| c == 'o')),
        "Board should contain power pellets"
    );
 }
--- a/tests/direction.rs
+++ b/tests/direction.rs
@@ -1,5 +1,5 @@
 use glam::IVec2;
-use pacman::entity::direction::*;
+use pacman::map::direction::*;
 #[test]
 fn test_direction_opposite() {
--- a/tests/error.rs
+++ b/tests/error.rs
@@ -0,0 +1,158 @@
 use pacman::error::{
    AnimatedTextureError, AssetError, EntityError, GameError, GameResult, IntoGameError, MapError, OptionExt, ParseError,
    ResultExt, TextureError,
 };
 use std::io;
 #[test]
 fn test_game_error_from_asset_error() {
    let asset_error = AssetError::NotFound("test.png".to_string());
    let game_error: GameError = asset_error.into();
    assert!(matches!(game_error, GameError::Asset(_)));
 }
 #[test]
 fn test_game_error_from_parse_error() {
    let parse_error = ParseError::UnknownCharacter('Z');
    let game_error: GameError = parse_error.into();
    assert!(matches!(game_error, GameError::MapParse(_)));
 }
 #[test]
 fn test_game_error_from_map_error() {
    let map_error = MapError::NodeNotFound(42);
    let game_error: GameError = map_error.into();
    assert!(matches!(game_error, GameError::Map(_)));
 }
 #[test]
 fn test_game_error_from_texture_error() {
    let texture_error = TextureError::LoadFailed("Failed to load".to_string());
    let game_error: GameError = texture_error.into();
    assert!(matches!(game_error, GameError::Texture(_)));
 }
 #[test]
 fn test_game_error_from_entity_error() {
    let entity_error = EntityError::NodeNotFound(10);
    let game_error: GameError = entity_error.into();
    assert!(matches!(game_error, GameError::Entity(_)));
 }
 #[test]
 fn test_game_error_from_io_error() {
    let io_error = io::Error::new(io::ErrorKind::NotFound, "File not found");
    let game_error: GameError = io_error.into();
    assert!(matches!(game_error, GameError::Io(_)));
 }
 #[test]
 fn test_texture_error_from_animated_error() {
    let animated_error = AnimatedTextureError::InvalidFrameDuration(-1.0);
    let texture_error: TextureError = animated_error.into();
    assert!(matches!(texture_error, TextureError::Animated(_)));
 }
 #[test]
 fn test_asset_error_from_io_error() {
    let io_error = io::Error::new(io::ErrorKind::PermissionDenied, "Permission denied");
    let asset_error: AssetError = io_error.into();
    assert!(matches!(asset_error, AssetError::Io(_)));
 }
 #[test]
 fn test_parse_error_display() {
    let error = ParseError::UnknownCharacter('!');
    assert_eq!(error.to_string(), "Unknown character in board: !");
    let error = ParseError::InvalidHouseDoorCount(3);
    assert_eq!(error.to_string(), "House door must have exactly 2 positions, found 3");
 }
 #[test]
 fn test_entity_error_display() {
    let error = EntityError::NodeNotFound(42);
    assert_eq!(error.to_string(), "Node not found in graph: 42");
    let error = EntityError::EdgeNotFound { from: 1, to: 2 };
    assert_eq!(error.to_string(), "Edge not found: from 1 to 2");
 }
 #[test]
 fn test_animated_texture_error_display() {
    let error = AnimatedTextureError::InvalidFrameDuration(0.0);
    assert_eq!(error.to_string(), "Frame duration must be positive, got 0");
 }
 #[test]
 fn test_into_game_error_trait() {
    let result: Result<i32, io::Error> = Err(io::Error::new(io::ErrorKind::Other, "test error"));
    let game_result: GameResult<i32> = result.into_game_error();
    assert!(game_result.is_err());
    if let Err(GameError::InvalidState(msg)) = game_result {
        assert!(msg.contains("test error"));
    } else {
        panic!("Expected InvalidState error");
    }
 }
 #[test]
 fn test_into_game_error_trait_success() {
    let result: Result<i32, io::Error> = Ok(42);
    let game_result: GameResult<i32> = result.into_game_error();
    assert_eq!(game_result.unwrap(), 42);
 }
 #[test]
 fn test_option_ext_some() {
    let option: Option<i32> = Some(42);
    let result: GameResult<i32> = option.ok_or_game_error(|| GameError::InvalidState("Not found".to_string()));
    assert_eq!(result.unwrap(), 42);
 }
 #[test]
 fn test_option_ext_none() {
    let option: Option<i32> = None;
    let result: GameResult<i32> = option.ok_or_game_error(|| GameError::InvalidState("Not found".to_string()));
    assert!(result.is_err());
    if let Err(GameError::InvalidState(msg)) = result {
        assert_eq!(msg, "Not found");
    } else {
        panic!("Expected InvalidState error");
    }
 }
 #[test]
 fn test_result_ext_success() {
    let result: Result<i32, io::Error> = Ok(42);
    let game_result: GameResult<i32> = result.with_context(|_| GameError::InvalidState("Context".to_string()));
    assert_eq!(game_result.unwrap(), 42);
 }
 #[test]
 fn test_result_ext_error() {
    let result: Result<i32, io::Error> = Err(io::Error::new(io::ErrorKind::Other, "original error"));
    let game_result: GameResult<i32> = result.with_context(|_| GameError::InvalidState("Context error".to_string()));
    assert!(game_result.is_err());
    if let Err(GameError::InvalidState(msg)) = game_result {
        assert_eq!(msg, "Context error");
    } else {
        panic!("Expected InvalidState error");
    }
 }
 #[test]
 fn test_error_chain_conversions() {
    // Test that we can convert through multiple levels
    let animated_error = AnimatedTextureError::InvalidFrameDuration(-5.0);
    let texture_error: TextureError = animated_error.into();
    let game_error: GameError = texture_error.into();
    assert!(matches!(game_error, GameError::Texture(TextureError::Animated(_))));
 }
--- a/tests/events.rs
+++ b/tests/events.rs
@@ -0,0 +1,117 @@
 use pacman::events::{GameCommand, GameEvent};
 use pacman::map::direction::Direction;
 #[test]
 fn test_game_command_variants() {
    // Test that all GameCommand variants can be created
    let commands = vec![
        GameCommand::Exit,
        GameCommand::MovePlayer(Direction::Up),
        GameCommand::MovePlayer(Direction::Down),
        GameCommand::MovePlayer(Direction::Left),
        GameCommand::MovePlayer(Direction::Right),
        GameCommand::ToggleDebug,
        GameCommand::MuteAudio,
        GameCommand::ResetLevel,
        GameCommand::TogglePause,
    ];
    // Just verify they can be created and compared
    assert_eq!(commands.len(), 9);
    assert_eq!(commands[0], GameCommand::Exit);
    assert_eq!(commands[1], GameCommand::MovePlayer(Direction::Up));
 }
 #[test]
 fn test_game_command_equality() {
    assert_eq!(GameCommand::Exit, GameCommand::Exit);
    assert_eq!(GameCommand::ToggleDebug, GameCommand::ToggleDebug);
    assert_eq!(
        GameCommand::MovePlayer(Direction::Left),
        GameCommand::MovePlayer(Direction::Left)
    );
    assert_ne!(GameCommand::Exit, GameCommand::ToggleDebug);
    assert_ne!(
        GameCommand::MovePlayer(Direction::Left),
        GameCommand::MovePlayer(Direction::Right)
    );
 }
 #[test]
 fn test_game_command_copy_clone() {
    let original = GameCommand::MovePlayer(Direction::Up);
    let copied = original;
    let cloned = original.clone();
    assert_eq!(original, copied);
    assert_eq!(original, cloned);
    assert_eq!(copied, cloned);
 }
 #[test]
 fn test_game_event_variants() {
    let command_event = GameEvent::Command(GameCommand::Exit);
    let collision_event = GameEvent::Collision(bevy_ecs::entity::Entity::from_raw(1), bevy_ecs::entity::Entity::from_raw(2));
    // Test that events can be created and compared
    assert_eq!(command_event, GameEvent::Command(GameCommand::Exit));
    assert_ne!(command_event, collision_event);
 }
 #[test]
 fn test_game_command_to_game_event_conversion() {
    let command = GameCommand::ToggleDebug;
    let event: GameEvent = command.into();
    assert_eq!(event, GameEvent::Command(GameCommand::ToggleDebug));
 }
 #[test]
 fn test_game_command_to_game_event_conversion_all_variants() {
    let commands = vec![
        GameCommand::Exit,
        GameCommand::MovePlayer(Direction::Up),
        GameCommand::ToggleDebug,
        GameCommand::MuteAudio,
        GameCommand::ResetLevel,
        GameCommand::TogglePause,
    ];
    for command in commands {
        let event: GameEvent = command.into();
        assert_eq!(event, GameEvent::Command(command));
    }
 }
 #[test]
 fn test_move_player_all_directions() {
    let directions = [Direction::Up, Direction::Down, Direction::Left, Direction::Right];
    for direction in directions {
        let command = GameCommand::MovePlayer(direction);
        let event: GameEvent = command.into();
        if let GameEvent::Command(GameCommand::MovePlayer(dir)) = event {
            assert_eq!(dir, direction);
        } else {
            panic!("Expected MovePlayer command with direction {:?}", direction);
        }
    }
 }
 #[test]
 fn test_game_event_debug_format() {
    let event = GameEvent::Command(GameCommand::Exit);
    let debug_str = format!("{:?}", event);
    assert!(debug_str.contains("Command"));
    assert!(debug_str.contains("Exit"));
 }
 #[test]
 fn test_game_command_debug_format() {
    let command = GameCommand::MovePlayer(Direction::Left);
    let debug_str = format!("{:?}", command);
    assert!(debug_str.contains("MovePlayer"));
    assert!(debug_str.contains("Left"));
 }
--- a/tests/formatting.rs
+++ b/tests/formatting.rs
@@ -19,7 +19,7 @@ fn get_formatted_output() -> impl IntoIterator<Item = String> {
 }
 #[test]
-fn test_formatting_alignment() {
+fn test_complex_formatting_alignment() {
    let mut colon_positions = vec![];
    let mut first_decimal_positions = vec![];
    let mut second_decimal_positions = vec![];
@@ -93,3 +93,80 @@ fn test_formatting_alignment() {
        second_unit_positions
    );
 }
 #[test]
 fn test_format_timing_display_basic() {
    let timing_data = vec![
        ("render".to_string(), Duration::from_micros(1500), Duration::from_micros(200)),
        ("input".to_string(), Duration::from_micros(300), Duration::from_micros(50)),
        ("physics".to_string(), Duration::from_nanos(750), Duration::from_nanos(100)),
    ];
    let formatted = format_timing_display(timing_data);
    // Should have 3 lines (one for each system)
    assert_eq!(formatted.len(), 3);
    // Each line should contain the system name
    assert!(formatted.iter().any(|line| line.contains("render")));
    assert!(formatted.iter().any(|line| line.contains("input")));
    assert!(formatted.iter().any(|line| line.contains("physics")));
    // Each line should contain timing information with proper units
    for line in formatted.iter() {
        assert!(line.contains(":"), "Line should contain colon separator: {}", line);
        assert!(line.contains("±"), "Line should contain ± symbol: {}", line);
    }
 }
 #[test]
 fn test_format_timing_display_empty() {
    let timing_data = vec![];
    let formatted = format_timing_display(timing_data);
    assert!(formatted.is_empty());
 }
 #[test]
 fn test_format_timing_display_units() {
    let timing_data = vec![
        ("seconds".to_string(), Duration::from_secs(2), Duration::from_millis(100)),
        ("millis".to_string(), Duration::from_millis(15), Duration::from_micros(200)),
        ("micros".to_string(), Duration::from_micros(500), Duration::from_nanos(50)),
        ("nanos".to_string(), Duration::from_nanos(250), Duration::from_nanos(25)),
    ];
    let formatted = format_timing_display(timing_data);
    // Check that appropriate units are used
    let all_lines = formatted.join(" ");
    assert!(all_lines.contains("s"), "Should contain seconds unit");
    assert!(all_lines.contains("ms"), "Should contain milliseconds unit");
    assert!(all_lines.contains("µs"), "Should contain microseconds unit");
    assert!(all_lines.contains("ns"), "Should contain nanoseconds unit");
 }
 #[test]
 fn test_format_timing_display_alignment() {
    let timing_data = vec![
        ("short".to_string(), Duration::from_micros(100), Duration::from_micros(10)),
        (
            "very_long_name".to_string(),
            Duration::from_micros(200),
            Duration::from_micros(20),
        ),
    ];
    let formatted = format_timing_display(timing_data);
    // Find colon positions - they should be aligned
    let colon_positions: Vec<usize> = formatted.iter().map(|line| line.find(':').unwrap_or(0)).collect();
    // All colons should be at the same position (aligned)
    if colon_positions.len() > 1 {
        let first_pos = colon_positions[0];
        assert!(
            colon_positions.iter().all(|&pos| pos == first_pos),
            "Colons should be aligned at the same position"
        );
    }
 }
--- a/tests/graph.rs
+++ b/tests/graph.rs
@@ -1,5 +1,5 @@
-use pacman::entity::direction::Direction;
+use pacman::map::direction::Direction;
-use pacman::entity::graph::{Graph, Node, TraversalFlags};
+use pacman::map::graph::{Graph, Node, TraversalFlags};
 fn create_test_graph() -> Graph {
    let mut graph = Graph::new();
--- a/tests/helpers.rs
+++ b/tests/helpers.rs
@@ -1,19 +0,0 @@
 use glam::{IVec2, UVec2};
 use pacman::helpers::centered_with_size;
 #[test]
 fn test_centered_with_size() {
    let test_cases = [
        ((100, 100), (50, 30), (75, 85)),
        ((50, 50), (51, 31), (25, 35)),
        ((0, 0), (100, 100), (-50, -50)),
        ((-100, -50), (80, 40), (-140, -70)),
        ((1000, 1000), (1000, 1000), (500, 500)),
    ];
    for ((pos_x, pos_y), (size_x, size_y), (expected_x, expected_y)) in test_cases {
        let rect = centered_with_size(IVec2::new(pos_x, pos_y), UVec2::new(size_x, size_y));
        assert_eq!(rect.origin(), (expected_x, expected_y));
        assert_eq!(rect.size(), (size_x, size_y));
    }
 }
--- a/tests/item.rs
+++ b/tests/item.rs
@@ -1,46 +0,0 @@
 // use glam::U16Vec2;
 // use pacman::texture::sprite::{AtlasTile, Sprite};
 // #[test]
 // fn test_item_type_get_score() {
 //     assert_eq!(ItemType::Pellet.get_score(), 10);
 //     assert_eq!(ItemType::Energizer.get_score(), 50);
 //     let fruit = ItemType::Fruit { kind: FruitKind::Apple };
 //     assert_eq!(fruit.get_score(), 100);
 // }
 // #[test]
 // fn test_fruit_kind_increasing_score() {
 //     // Build a list of fruit kinds, sorted by their index
 //     let mut kinds = FruitKind::iter()
 //         .map(|kind| (kind.index(), kind.get_score()))
 //         .collect::<Vec<_>>();
 //     kinds.sort_unstable_by_key(|(index, _)| *index);
 //     assert_eq!(kinds.len(), FruitKind::COUNT);
 //     // Check that the score increases as expected
 //     for window in kinds.windows(2) {
 //         let ((_, prev), (_, next)) = (window[0], window[1]);
 //         assert!(prev < next, "Fruits should have increasing scores, but {prev:?} < {next:?}");
 //     }
 // }
 // #[test]
 // fn test_item_creation_and_collection() {
 //     let atlas_tile = AtlasTile {
 //         pos: U16Vec2::new(0, 0),
 //         size: U16Vec2::new(16, 16),
 //         color: None,
 //     };
 //     let sprite = Sprite::new(atlas_tile);
 //     let mut item = Item::new(0, ItemType::Pellet, sprite);
 //     assert!(!item.is_collected());
 //     assert_eq!(item.get_score(), 10);
 //     assert_eq!(item.position().from_node_id(), 0);
 //     item.collect();
 //     assert!(item.is_collected());
 // }
Author	SHA1	Message	Date
Xevion	9c0711a54c	test: add more formatting tests	2025-08-17 23:47:47 -05:00
Xevion	4598dc07e2	test: add tests for errors & events data structs	2025-08-17 23:46:23 -05:00
Xevion	9c9dc5f423	test: remove asset.rs tests, revamp constants tests	2025-08-17 23:45:42 -05:00
Xevion	12ee16faab	docs: document many major functions, types, enums for important functionality	2025-08-17 23:29:43 -05:00
Xevion	398d041d96	Merge pull request #3 from Xevion/ecs ECS Refactor	2025-08-16 15:25:34 -05:00
Xevion	7a02d6b0b5	chore: add cargo checks to pre-commit	2025-08-16 15:14:16 -05:00
Xevion	d47d70ff5b	refactor: remove dead code, move direction & graph into 'map' module	2025-08-16 15:14:16 -05:00