//! This example showcases a 3D first-person camera. //! //! The setup presented here is a very common way of organizing a first-person game //! where the player can see their own arms. We use two industry terms to differentiate //! the kinds of models we have: //! //! - The *view model* is the model that represents the player's body. //! - The *world model* is everything else. //! //! ## Motivation //! //! The reason for this distinction is that these two models should be rendered with different field of views (FOV). //! The view model is typically designed and animated with a very specific FOV in mind, so it is //! generally *fixed* and cannot be changed by a player. The world model, on the other hand, should //! be able to change its FOV to accommodate the player's preferences for the following reasons: //! - *Accessibility*: How prone is the player to motion sickness? A wider FOV can help. //! - *Tactical preference*: Does the player want to see more of the battlefield? //! Or have a more zoomed-in view for precision aiming? //! - *Physical considerations*: How well does the in-game FOV match the player's real-world FOV? //! Are they sitting in front of a monitor or playing on a TV in the living room? How big is the screen? //! //! ## Implementation //! //! The `Player` is an entity holding two cameras, one for each model. The view model camera has a fixed //! FOV of 70 degrees, while the world model camera has a variable FOV that can be changed by the player. //! //! We use different `RenderLayers` to select what to render. //! //! - The world model camera has no explicit `RenderLayers` component, so it uses the layer 0. //! All static objects in the scene are also on layer 0 for the same reason. //! - The view model camera has a `RenderLayers` component with layer 1, so it only renders objects //! explicitly assigned to layer 1. The arm of the player is one such object. //! The order of the view model camera is additionally bumped to 1 to ensure it renders on top of the world model. //! - The light source in the scene must illuminate both the view model and the world model, so it is //! assigned to both layers 0 and 1. //! //! ## Controls //! //! | Key Binding | Action | //! |:---------------------|:--------------| //! | mouse | Look around | //! | arrow up | Decrease FOV | //! | arrow down | Increase FOV | use std::f32::consts::FRAC_PI_2; use bevy::{ color::palettes::tailwind, input::mouse::AccumulatedMouseMotion, pbr::NotShadowCaster, prelude::*, render::view::RenderLayers, }; fn main() { App::new() .add_plugins(DefaultPlugins) .add_systems( Startup, ( spawn_view_model, spawn_world_model, spawn_lights, spawn_text, ), ) .add_systems(Update, (move_player, change_fov)) .run(); } #[derive(Debug, Component)] struct Player; #[derive(Debug, Component, Deref, DerefMut)] struct CameraSensitivity(Vec2); impl Default for CameraSensitivity { fn default() -> Self { Self( // These factors are just arbitrary mouse sensitivity values. // It's often nicer to have a faster horizontal sensitivity than vertical. // We use a component for them so that we can make them user-configurable at runtime // for accessibility reasons. // It also allows you to inspect them in an editor if you `Reflect` the component. Vec2::new(0.003, 0.002), ) } } #[derive(Debug, Component)] struct WorldModelCamera; /// Used implicitly by all entities without a `RenderLayers` component. /// Our world model camera and all objects other than the player are on this layer. /// The light source belongs to both layers. const DEFAULT_RENDER_LAYER: usize = 0; /// Used by the view model camera and the player's arm. /// The light source belongs to both layers. const VIEW_MODEL_RENDER_LAYER: usize = 1; fn spawn_view_model( mut commands: Commands, mut meshes: ResMut>, mut materials: ResMut>, ) { let arm = meshes.add(Cuboid::new(0.1, 0.1, 0.5)); let arm_material = materials.add(Color::from(tailwind::TEAL_200)); commands .spawn(( Player, CameraSensitivity::default(), Transform::from_xyz(0.0, 1.0, 0.0), Visibility::default(), )) .with_children(|parent| { parent.spawn(( WorldModelCamera, Camera3d::default(), Projection::from(PerspectiveProjection { fov: 90.0_f32.to_radians(), ..default() }), )); // Spawn view model camera. parent.spawn(( Camera3d::default(), Camera { // Bump the order to render on top of the world model. order: 1, ..default() }, Projection::from(PerspectiveProjection { fov: 70.0_f32.to_radians(), ..default() }), // Only render objects belonging to the view model. RenderLayers::layer(VIEW_MODEL_RENDER_LAYER), )); // Spawn the player's right arm. parent.spawn(( Mesh3d(arm), MeshMaterial3d(arm_material), Transform::from_xyz(0.2, -0.1, -0.25), // Ensure the arm is only rendered by the view model camera. RenderLayers::layer(VIEW_MODEL_RENDER_LAYER), // The arm is free-floating, so shadows would look weird. NotShadowCaster, )); }); } fn spawn_world_model( mut commands: Commands, mut meshes: ResMut>, mut materials: ResMut>, ) { let floor = meshes.add(Plane3d::new(Vec3::Y, Vec2::splat(10.0))); let cube = meshes.add(Cuboid::new(2.0, 0.5, 1.0)); let material = materials.add(Color::WHITE); // The world model camera will render the floor and the cubes spawned in this system. // Assigning no `RenderLayers` component defaults to layer 0. commands.spawn((Mesh3d(floor), MeshMaterial3d(material.clone()))); commands.spawn(( Mesh3d(cube.clone()), MeshMaterial3d(material.clone()), Transform::from_xyz(0.0, 0.25, -3.0), )); commands.spawn(( Mesh3d(cube), MeshMaterial3d(material), Transform::from_xyz(0.75, 1.75, 0.0), )); } fn spawn_lights(mut commands: Commands) { commands.spawn(( PointLight { color: Color::from(tailwind::ROSE_300), shadows_enabled: true, ..default() }, Transform::from_xyz(-2.0, 4.0, -0.75), // The light source illuminates both the world model and the view model. RenderLayers::from_layers(&[DEFAULT_RENDER_LAYER, VIEW_MODEL_RENDER_LAYER]), )); } fn spawn_text(mut commands: Commands) { commands .spawn(Node { position_type: PositionType::Absolute, bottom: Val::Px(12.0), left: Val::Px(12.0), ..default() }) .with_child(Text::new(concat!( "Move the camera with your mouse.\n", "Press arrow up to decrease the FOV of the world model.\n", "Press arrow down to increase the FOV of the world model." ))); } fn move_player( accumulated_mouse_motion: Res, mut player: Query<(&mut Transform, &CameraSensitivity), With>, ) { let Ok((mut transform, camera_sensitivity)) = player.get_single_mut() else { return; }; let delta = accumulated_mouse_motion.delta; if delta != Vec2::ZERO { // Note that we are not multiplying by delta_time here. // The reason is that for mouse movement, we already get the full movement that happened since the last frame. // This means that if we multiply by delta_time, we will get a smaller rotation than intended by the user. // This situation is reversed when reading e.g. analog input from a gamepad however, where the same rules // as for keyboard input apply. Such an input should be multiplied by delta_time to get the intended rotation // independent of the framerate. let delta_yaw = -delta.x * camera_sensitivity.x; let delta_pitch = -delta.y * camera_sensitivity.y; let (yaw, pitch, roll) = transform.rotation.to_euler(EulerRot::YXZ); let yaw = yaw + delta_yaw; // If the pitch was ±¹⁄₂ π, the camera would look straight up or down. // When the user wants to move the camera back to the horizon, which way should the camera face? // The camera has no way of knowing what direction was "forward" before landing in that extreme position, // so the direction picked will for all intents and purposes be arbitrary. // Another issue is that for mathematical reasons, the yaw will effectively be flipped when the pitch is at the extremes. // To not run into these issues, we clamp the pitch to a safe range. const PITCH_LIMIT: f32 = FRAC_PI_2 - 0.01; let pitch = (pitch + delta_pitch).clamp(-PITCH_LIMIT, PITCH_LIMIT); transform.rotation = Quat::from_euler(EulerRot::YXZ, yaw, pitch, roll); } } fn change_fov( input: Res>, mut world_model_projection: Query<&mut Projection, With>, ) { let Ok(mut projection) = world_model_projection.get_single_mut() else { return; }; let Projection::Perspective(ref mut perspective) = projection.as_mut() else { unreachable!( "The `Projection` component was explicitly built with `Projection::Perspective`" ); }; if input.pressed(KeyCode::ArrowUp) { perspective.fov -= 1.0_f32.to_radians(); perspective.fov = perspective.fov.max(20.0_f32.to_radians()); } if input.pressed(KeyCode::ArrowDown) { perspective.fov += 1.0_f32.to_radians(); perspective.fov = perspective.fov.min(160.0_f32.to_radians()); } }