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Author SHA1 Message Date
SeanOMik 35815fa019
Create a new crate! lyra-scene for representing a SceneGraph in an ECS world 2024-03-03 16:21:55 -05:00
SeanOMik b51f1e16ef
ecs: fix World::insert, finish a TODO related to it
The TODO was that if the archetype has a single entity, add a component column for the new component instead of moving the entity to a brand new archetype
2024-03-03 16:19:59 -05:00
12 changed files with 641 additions and 40 deletions

22
.vscode/launch.json vendored
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@ -83,6 +83,28 @@
}, },
"args": [], "args": [],
"cwd": "${workspaceFolder}/lyra-ecs" "cwd": "${workspaceFolder}/lyra-ecs"
},
{
"type": "lldb",
"request": "launch",
"name": "Debug unit tests in executable 'lyra-scene'",
"cargo": {
"args": [
"test",
"--no-run",
"--lib",
"--package=lyra-scene",
//"command::tests::deferred_commands",
//"--",
//"--exact --nocapture"
],
"filter": {
"name": "lyra-scene",
"kind": "lib"
}
},
"args": [],
"cwd": "${workspaceFolder}/lyra-scene"
} }
] ]
} }

8
Cargo.lock generated
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@ -1855,6 +1855,14 @@ dependencies = [
"uuid", "uuid",
] ]
[[package]]
name = "lyra-scene"
version = "0.1.0"
dependencies = [
"lyra-ecs",
"lyra-math",
]
[[package]] [[package]]
name = "lyra-scripting" name = "lyra-scripting"
version = "0.1.0" version = "0.1.0"

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@ -10,7 +10,7 @@ members = [
"lyra-ecs", "lyra-ecs",
"lyra-reflect", "lyra-reflect",
"lyra-scripting", "lyra-scripting",
"lyra-game", "lyra-math"] "lyra-game", "lyra-math", "lyra-scene"]
[features] [features]
scripting = ["dep:lyra-scripting"] scripting = ["dep:lyra-scripting"]

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@ -55,7 +55,6 @@ impl ComponentColumn {
/// Set a component from pointer at an entity index. /// Set a component from pointer at an entity index.
/// ///
/// # Safety /// # Safety
///
/// This column must have space to fit the component, if it does not have room it will panic. /// This column must have space to fit the component, if it does not have room it will panic.
pub unsafe fn set_at(&mut self, entity_index: usize, comp_src: NonNull<u8>, tick: Tick) { pub unsafe fn set_at(&mut self, entity_index: usize, comp_src: NonNull<u8>, tick: Tick) {
assert!(entity_index < self.capacity); assert!(entity_index < self.capacity);
@ -76,6 +75,23 @@ impl ComponentColumn {
} }
} }
/// Inserts an entity and its component at a specific index.
pub unsafe fn insert_entity(&mut self, entity_index: usize, comp_src: NonNull<u8>, tick: Tick) {
assert!(entity_index < self.capacity);
let mut data = self.data.borrow_mut();
let data = data.deref_mut();
let size = self.info.layout().size();
let dest = NonNull::new_unchecked(data.as_ptr().add(entity_index * size));
ptr::copy_nonoverlapping(comp_src.as_ptr(), dest.as_ptr(), size);
// check if a component spot is being set twice and that the entity's tick is
// already stored
self.entity_ticks.push(tick);
self.len += 1;
}
/// Get a component at an entities index. /// Get a component at an entities index.
/// ///
/// # Safety /// # Safety
@ -153,6 +169,8 @@ impl ComponentColumn {
pub unsafe fn remove_component(&mut self, entity_index: usize, tick: &Tick) -> Option<usize> { pub unsafe fn remove_component(&mut self, entity_index: usize, tick: &Tick) -> Option<usize> {
let _ = tick; // may be used at some point let _ = tick; // may be used at some point
debug_assert!(self.len > 0, "There are no entities in the Archetype to remove from!");
let mut data = self.data.borrow_mut(); let mut data = self.data.borrow_mut();
let data = data.deref_mut(); let data = data.deref_mut();
@ -170,8 +188,7 @@ impl ComponentColumn {
mem::swap(&mut old_comp_ptr, &mut new_comp_ptr); // new_comp_ptr is now the old ptr mem::swap(&mut old_comp_ptr, &mut new_comp_ptr); // new_comp_ptr is now the old ptr
// make sure to keep entity indexes correct in the ticks list as well // make sure to keep entity indexes correct in the ticks list as well
self.entity_ticks.swap(moved_index, entity_index); self.entity_ticks.swap_remove(entity_index);
self.entity_ticks.pop();
Some(moved_index) Some(moved_index)
} else { None }; } else { None };
@ -283,8 +300,7 @@ impl Archetype {
bundle.take(|data, type_id, _size| { bundle.take(|data, type_id, _size| {
let col = self.get_column_mut(type_id).unwrap(); let col = self.get_column_mut(type_id).unwrap();
unsafe { col.set_at(entity_index.0 as usize, data, *tick); } unsafe { col.insert_entity(entity_index.0 as usize, data, *tick); }
col.len += 1;
}); });
entity_index entity_index
@ -293,21 +309,21 @@ impl Archetype {
/// Removes an entity from the Archetype and frees its components. Returns the entity record /// Removes an entity from the Archetype and frees its components. Returns the entity record
/// that took its place in the component column. /// that took its place in the component column.
pub(crate) fn remove_entity(&mut self, entity: Entity, tick: &Tick) -> Option<(Entity, ArchetypeEntityId)> { pub(crate) fn remove_entity(&mut self, entity: Entity, tick: &Tick) -> Option<(Entity, ArchetypeEntityId)> {
let entity_index = *self.entity_ids.get(&entity) let entity_index = self.entity_ids.remove(&entity)
.expect("The entity is not in this Archetype!"); .expect("The entity is not in this Archetype!");
let mut removed_entity: Option<(Entity, ArchetypeEntityId)> = None; let mut removed_entity: Option<(Entity, ArchetypeEntityId)> = None;
for c in self.columns.iter_mut() { for c in self.columns.iter_mut() {
let moved_entity = unsafe { c.remove_component(entity_index.0 as usize, tick) }; let moved_entity = unsafe { c.remove_component(entity_index.0 as usize, tick) };
if let Some(res) = moved_entity { if let Some(moved_idx) = moved_entity {
if let Some((_, aid)) = removed_entity { if let Some((_, aid)) = removed_entity {
// Make sure that the moved entity is the same as what was moved in other columns. // Make sure that the moved entity is the same as what was moved in other columns.
assert!(res as u64 == aid.0); assert!(moved_idx as u64 == aid.0);
} else { } else {
// This is the first move, so find the EntityId that points to the column index. // This is the first move, so find the Entity that was moved into this index.
let just_removed = self.entities[res]; let just_removed = self.entities[moved_idx];
removed_entity = Some((just_removed, ArchetypeEntityId(res as u64))); removed_entity = Some((just_removed, ArchetypeEntityId(moved_idx as u64)));
} }
} else { } else {
// If there wasn't a moved entity, make sure no other columns moved something. // If there wasn't a moved entity, make sure no other columns moved something.
@ -316,12 +332,15 @@ impl Archetype {
} }
// safe from the .expect at the start of this method. // safe from the .expect at the start of this method.
self.entity_ids.remove(&entity).unwrap(); //self.entity_ids.remove(&entity).unwrap();
if self.entities.len() > 1 {
let len = self.entities.len(); // update the archetype index of the moved entity
self.entities.swap(entity_index.0 as _, len - 1); if let Some((moved, _old_idx)) = removed_entity {
self.entity_ids.insert(moved, entity_index);
} }
self.entities.pop().unwrap();
let removed = self.entities.swap_remove(entity_index.0 as _);
assert_eq!(removed, entity);
// now change the ArchetypeEntityId to be the index that the moved entity was moved into. // now change the ArchetypeEntityId to be the index that the moved entity was moved into.
removed_entity.map(|(e, _a)| (e, entity_index)) removed_entity.map(|(e, _a)| (e, entity_index))
@ -390,7 +409,8 @@ impl Archetype {
self.capacity = new_cap; self.capacity = new_cap;
} }
debug_assert_eq!(self.entity_ids.len(), self.entities.len(), "Somehow the Archetype's entity storage got unsynced"); debug_assert_eq!(self.entity_ids.len(), self.entities.len(),
"Somehow the Archetype's entity storage got unsynced");
let entity_index = ArchetypeEntityId(self.entity_ids.len() as u64); let entity_index = ArchetypeEntityId(self.entity_ids.len() as u64);
self.entity_ids.insert(entity, entity_index); self.entity_ids.insert(entity, entity_index);
self.entities.push(entity); self.entities.push(entity);
@ -402,6 +422,12 @@ impl Archetype {
entity_index entity_index
} }
/// Ensure that the internal entity lists are synced in length
pub(crate) fn ensure_synced(&self) {
debug_assert_eq!(self.entity_ids.len(), self.entities.len(),
"Somehow the Archetype's entity storage got unsynced");
}
/// Moves the entity from this archetype into another one. /// Moves the entity from this archetype into another one.
/// ///
/// # Safety /// # Safety
@ -453,6 +479,36 @@ impl Archetype {
pub fn has_entity(&self, e: Entity) -> bool { pub fn has_entity(&self, e: Entity) -> bool {
self.entity_ids.contains_key(&e) self.entity_ids.contains_key(&e)
} }
/// Extend the Archetype by adding more columns.
///
/// In order to extend the Archetype, the archetype needs the components for the entities
/// it already has. These are provided through the `new_columns` parameter. **If the Vec
/// does not have the same amount of bundles in it as the amount of entities in the
/// Archetype, it will panic!**
pub fn extend<B: Bundle>(&mut self, tick: &Tick, new_columns: Vec<B>) {
debug_assert_eq!(new_columns.len(), self.len(), "The amount of provided column does not \
match the amount of entities");
let column_info = new_columns.iter()
.next()
.unwrap()
.info();
for coli in column_info.into_iter() {
let col = unsafe { ComponentColumn::new(coli, self.capacity) };
self.columns.push(col);
}
for (eid, bundle) in new_columns.into_iter().enumerate() {
bundle.take(|ptr, tyid, _size| {
unsafe {
let col = self.get_column_mut(tyid).unwrap();
col.insert_entity(eid, ptr, tick.clone());
}
});
}
}
} }
#[cfg(test)] #[cfg(test)]
@ -666,4 +722,24 @@ mod tests {
assert_eq!(unsafe { *ptr.cast::<u32>().as_ref() }, comp); assert_eq!(unsafe { *ptr.cast::<u32>().as_ref() }, comp);
assert_eq!(col.info, info); assert_eq!(col.info, info);
} }
/// Tests removing an entity from the Archetype when it is the only entity in it.
#[test]
fn remove_single_entity() {
let info = (Vec2::new(0.0, 0.0),).info();
let mut a = Archetype::from_bundle_info(super::ArchetypeId(0), info);
let ae = Entity {
id: EntityId(0),
generation: 0
};
a.add_entity(
ae,
Vec2::new(10.0, 50.0),
&Tick::default()
);
a.remove_entity(ae, &Tick::default());
}
} }

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@ -30,7 +30,7 @@ pub use component::*;
pub mod query; pub mod query;
//pub use query::*; //pub use query::*;
mod relation; pub mod relation;
pub use relation::Relation; pub use relation::Relation;
mod component_info; mod component_info;

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@ -0,0 +1,8 @@
use super::Relation;
// TODO: Delete child entities when the parent is deleted
pub struct ChildOf;
impl Relation for ChildOf {
}

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@ -10,19 +10,20 @@ use crate::lyra_engine;
use crate::World; use crate::World;
mod relates_to; mod relates_to;
#[doc(hidden)]
pub use relates_to::*; pub use relates_to::*;
mod relate_pair; mod relate_pair;
#[doc(hidden)]
pub use relate_pair::*; pub use relate_pair::*;
mod child_of;
pub use child_of::*;
#[allow(unused_variables)] #[allow(unused_variables)]
pub trait Relation: 'static { pub trait Relation: 'static {
/// called when a relation of this type is set on a target /// called when a relation of this type is set on a target
fn relation_add(&self, origin: Entity, target: Entity) { } fn relation_add(&mut self, world: &mut World, origin: Entity, target: Entity) { }
/// called when a relation is removed /// called when a relation is removed
fn relation_remove(&self, origin: Entity, target: Entity) { } fn relation_remove(&mut self, world: &mut World, origin: Entity, target: Entity) { }
} }
/// A component that stores the target of a relation. /// A component that stores the target of a relation.
@ -31,10 +32,16 @@ pub trait Relation: 'static {
/// entities that the relation targets. /// entities that the relation targets.
#[derive(Component)] #[derive(Component)]
pub struct RelationOriginComponent<R: Relation> { pub struct RelationOriginComponent<R: Relation> {
pub(crate) relation: R, pub relation: R,
target: Entity, target: Entity,
} }
impl<R: Relation> RelationOriginComponent<R> {
pub fn target(&self) -> Entity {
self.target
}
}
/// A component that stores the origin of a relation. /// A component that stores the origin of a relation.
/// ///
/// This component is on the target of the relation and can be used to find the /// This component is on the target of the relation and can be used to find the
@ -79,12 +86,12 @@ impl World {
}; };
self.insert(target, comp); self.insert(target, comp);
let comp = RelationOriginComponent { let mut comp = RelationOriginComponent {
relation, relation,
target, target,
}; };
comp.relation.relation_add(origin, target); comp.relation.relation_add(self, origin, target);
self.insert(origin, comp); self.insert(origin, comp);
} }
} }

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@ -69,7 +69,7 @@ where
unsafe fn fetch<'a>(&self, _world: &'a World, archetype: &'a crate::archetype::Archetype, tick: crate::Tick) -> Self::Fetch<'a> { unsafe fn fetch<'a>(&self, _world: &'a World, archetype: &'a crate::archetype::Archetype, tick: crate::Tick) -> Self::Fetch<'a> {
let _ = tick; let _ = tick;
let col = archetype.get_column(self.type_id()) let col = archetype.get_column(TypeId::of::<RelationOriginComponent<R>>())
.expect("You ignored 'can_visit_archetype'!"); .expect("You ignored 'can_visit_archetype'!");
FetchRelatePair { FetchRelatePair {

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@ -133,8 +133,6 @@ impl World {
where where
B: Bundle B: Bundle
{ {
// TODO: If the archetype has a single entity, add a component column for the new
// component instead of moving the entity to a brand new archetype.
// TODO: If the entity already has the components in `bundle`, update the values of the // TODO: If the entity already has the components in `bundle`, update the values of the
// components with the bundle. // components with the bundle.
@ -142,6 +140,7 @@ impl World {
let record = self.entities.entity_record(entity).unwrap(); let record = self.entities.entity_record(entity).unwrap();
let current_arch = self.archetypes.get(&record.id).unwrap(); let current_arch = self.archetypes.get(&record.id).unwrap();
let current_arch_len = current_arch.len();
let mut col_types: Vec<DynTypeId> = current_arch.columns.iter().map(|c| c.info.type_id()).collect(); let mut col_types: Vec<DynTypeId> = current_arch.columns.iter().map(|c| c.info.type_id()).collect();
let orig_col = col_types.clone(); let orig_col = col_types.clone();
@ -150,7 +149,9 @@ impl World {
let mut col_infos: Vec<ComponentInfo> = current_arch.columns.iter().map(|c| c.info).collect(); let mut col_infos: Vec<ComponentInfo> = current_arch.columns.iter().map(|c| c.info).collect();
col_infos.extend(bundle.info()); col_infos.extend(bundle.info());
let col_ptrs: Vec<(NonNull<u8>, ComponentInfo)> = current_arch.columns.iter().map(|c| unsafe { (NonNull::new_unchecked(c.borrow_ptr().as_ptr()), c.info) }).collect(); let col_ptrs: Vec<(NonNull<u8>, ComponentInfo)> = current_arch.columns.iter()
.map(|c| unsafe { (NonNull::new_unchecked(c.borrow_ptr().as_ptr()), c.info) })
.collect();
if let Some(arch) = self.archetypes.values_mut().find(|a| a.is_archetype_for(&col_types)) { if let Some(arch) = self.archetypes.values_mut().find(|a| a.is_archetype_for(&col_types)) {
let res_index = arch.reserve_one(entity); let res_index = arch.reserve_one(entity);
@ -158,19 +159,21 @@ impl World {
for (col_type, (col_ptr, col_info)) in orig_col.into_iter().zip(col_ptrs.into_iter()) { for (col_type, (col_ptr, col_info)) in orig_col.into_iter().zip(col_ptrs.into_iter()) {
unsafe { unsafe {
let ptr = NonNull::new_unchecked(col_ptr.as_ptr() let ptr = NonNull::new_unchecked(col_ptr.as_ptr()
.add(res_index.0 as usize * col_info.layout().size())); .add(record.index.0 as usize * col_info.layout().size()));
let col = arch.get_column_mut(col_type).unwrap(); let col = arch.get_column_mut(col_type).unwrap();
// set_at is used since the entity was reserved
col.set_at(res_index.0 as _, ptr, tick); col.set_at(res_index.0 as _, ptr, tick);
} }
} }
bundle.take(|data, type_id, _size| { bundle.take(|data, type_id, _size| {
let col = arch.get_column_mut(type_id).unwrap(); let col = arch.get_column_mut(type_id).unwrap();
// set_at is used since the entity was reserved
unsafe { col.set_at(res_index.0 as _, data, tick); } unsafe { col.set_at(res_index.0 as _, data, tick); }
col.len += 1;
}); });
arch.entity_ids.insert(entity, res_index); arch.entity_ids.insert(entity, res_index);
arch.ensure_synced();
let new_record = Record { let new_record = Record {
id: arch.id(), id: arch.id(),
@ -178,10 +181,30 @@ impl World {
}; };
self.entities.insert_entity_record(entity, new_record); self.entities.insert_entity_record(entity, new_record);
} else { } else {
if current_arch_len == 1 {
// if this entity is the only entity for this archetype, add more columns to it
let current_arch = self.archetypes.get_mut(&record.id).unwrap();
current_arch.extend(&tick, vec![bundle]);
return;
}
let new_arch_id = self.next_archetype_id.increment(); let new_arch_id = self.next_archetype_id.increment();
let mut archetype = Archetype::from_bundle_info(new_arch_id, col_infos); let mut archetype = Archetype::from_bundle_info(new_arch_id, col_infos);
let entity_arch_id = archetype.add_entity(entity, bundle, &tick); let entity_arch_id = archetype.add_entity(entity, bundle, &tick);
// move the old components into the new archetype
for (column_ptr, column_info) in col_ptrs.into_iter() {
unsafe {
// ptr of component for the entity
let comp_ptr = NonNull::new_unchecked(column_ptr.as_ptr()
.add(record.index.0 as usize * column_info.layout().size()));
let col = archetype.get_column_mut(column_info.type_id()).unwrap();
col.insert_entity(entity_arch_id.0 as _, comp_ptr, tick);
}
}
self.archetypes.insert(new_arch_id, archetype); self.archetypes.insert(new_arch_id, archetype);
// Create entity record and store it // Create entity record and store it
@ -194,7 +217,13 @@ impl World {
} }
let current_arch = self.archetypes.get_mut(&record.id).unwrap(); let current_arch = self.archetypes.get_mut(&record.id).unwrap();
current_arch.remove_entity(entity, &tick); if current_arch.len() > 1 {
current_arch.remove_entity(entity, &tick);
} else if current_arch.len() == 1 {
// The old archetype will only be removed if there was another archetype that would
// work for the entity's components, and the old archetype only had a single entity.
self.archetypes.remove(&record.id).unwrap();
}
} }
pub fn entity_archetype(&self, entity: Entity) -> Option<&Archetype> { pub fn entity_archetype(&self, entity: Entity) -> Option<&Archetype> {
@ -330,7 +359,7 @@ impl World {
#[cfg(test)] #[cfg(test)]
mod tests { mod tests {
use crate::{tests::{Vec2, Vec3}, query::TickOf}; use crate::{query::TickOf, tests::{Vec2, Vec3}, Entity};
use super::World; use super::World;
@ -453,6 +482,46 @@ mod tests {
assert!(world.view_one::<&Vec3>(e).get().is_some()) assert!(world.view_one::<&Vec3>(e).get().is_some())
} }
#[test]
fn insert_multiple_times() {
let v2s = &[Vec2::rand(), Vec2::rand(), Vec2::rand()];
let v3s = &[Vec3::rand(), Vec3::rand(), Vec3::rand()];
let mut world = World::new();
let e1 = world.spawn(v2s[0]);
let e2 = world.spawn(v2s[1]);
let e3 = world.spawn(v2s[2]);
println!("Spawned entities");
let ev2 = world.view_one::<&Vec2>(e2).get()
.expect("Failed to find Vec2 and Vec3 on inserted entity!");
assert_eq!(*ev2, v2s[1]);
drop(ev2);
let insert_and_assert = |world: &mut World, e: Entity, v2: Vec2, v3: Vec3| {
println!("inserting entity");
world.insert(e, (v3,));
println!("inserted entity");
let (ev2, ev3) = world.view_one::<(&Vec2, &Vec3)>(e).get()
.expect("Failed to find Vec2 and Vec3 on inserted entity!");
assert_eq!(*ev2, v2);
assert_eq!(*ev3, v3);
};
insert_and_assert(&mut world, e2, v2s[1], v3s[1]);
println!("Entity 2 is good");
insert_and_assert(&mut world, e3, v2s[2], v3s[2]);
println!("Entity 3 is good");
assert_eq!(world.archetypes.len(), 2);
println!("No extra archetypes were created");
insert_and_assert(&mut world, e1, v2s[0], v3s[0]);
println!("Entity 1 is good");
assert_eq!(world.archetypes.len(), 1);
println!("Empty archetype was removed");
}
#[test] #[test]
fn view_one() { fn view_one() {
let v = Vec2::rand(); let v = Vec2::rand();
@ -468,11 +537,6 @@ mod tests {
fn view_change_tracking() { fn view_change_tracking() {
let mut world = World::new(); let mut world = World::new();
/* let v = Vec2::rand();
world.spawn((v,));
let v = Vec2::rand();
world.spawn((v,)); */
println!("spawning"); println!("spawning");
world.spawn((Vec2::new(10.0, 10.0),)); world.spawn((Vec2::new(10.0, 10.0),));
world.spawn((Vec2::new(5.0, 5.0),)); world.spawn((Vec2::new(5.0, 5.0),));

10
lyra-scene/Cargo.toml Normal file
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@ -0,0 +1,10 @@
[package]
name = "lyra-scene"
version = "0.1.0"
edition = "2021"
# See more keys and their definitions at https://doc.rust-lang.org/cargo/reference/manifest.html
[dependencies]
lyra-ecs = { path = "../lyra-ecs", features = [ "math" ] }
lyra-math = { path = "../lyra-math" }

305
lyra-scene/src/lib.rs Normal file
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@ -0,0 +1,305 @@
use std::{collections::VecDeque, ops::{Deref, DerefMut}};
use lyra_ecs::{query::Entities, relation::ChildOf, Bundle, Component, Entity, World};
// So we can use lyra_ecs::Component derive macro
pub(crate) mod lyra_engine {
pub(crate) mod ecs {
pub use lyra_ecs::*;
}
}
mod node;
use lyra_math::{Transform, Vec3};
pub use node::*;
/// A flag spawned on all scene node entities
#[derive(Component)]
pub struct SceneNodeFlag;
/// A flag spawned on only the scene root node
#[derive(Component)]
pub struct SceneNodeRoot;
enum MutCow<'a, T> {
Mut(&'a mut T),
Owned(T),
}
impl<'a, T> Deref for MutCow<'a, T> {
type Target = T;
fn deref(&self) -> &Self::Target {
match self {
MutCow::Mut(t) => t,
MutCow::Owned(t) => t,
}
}
}
impl<'a, T> DerefMut for MutCow<'a, T> {
fn deref_mut(&mut self) -> &mut Self::Target {
match self {
MutCow::Mut(t) => t,
MutCow::Owned(t) => t,
}
}
}
/// A SceneGraph is a Graph of nodes that represents the hierarchy of a scene.
///
/// This SceneGraph is special in the sense that it is literally just an ECS world with methods
/// implemented for it that make it easier to use for a SceneGraph.
//#[derive(Default)]
pub struct SceneGraph<'a> {
pub(crate) world: MutCow<'a, World>,
root_node: SceneNode,
}
impl<'a> SceneGraph<'a> {
/// Create a new SceneGraph with its own ECS World.
pub fn new() -> Self {
let mut world = World::new();
let e = world.spawn((Transform::from_translation(Vec3::new(0.0, 0.0, 0.0)), SceneNodeRoot));
let root = SceneNode::new(None, e);
Self {
world: MutCow::Owned(world),
root_node: root
}
}
/// Retrieve a SceneGraph from an ECS World.
///
/// Returns `None` if the `root_entity` was not created from a `SceneGraph` that was later
/// inserted into another world with [`SceneGraph::into_world`].
pub fn from_world(world: &'a mut World, root_entity: Entity) -> Option<Self> {
if world.view_one::<(&SceneNodeRoot, &Transform)>(root_entity).get().is_none() {
None
} else {
Some(Self {
world: MutCow::Mut(world),
root_node: SceneNode::new(None, root_entity),
})
}
}
/// Create a new SceneGraph inside an existing ECS World.
pub fn new_from_world(world: &'a mut World) -> Self {
let root_en = world.spawn((Transform::from_translation(Vec3::new(0.0, 0.0, 0.0)), SceneNodeRoot));
let root = SceneNode::new(None, root_en);
Self {
world: MutCow::Mut(world),
root_node: root,
}
}
/// Consume the SceneGraph, inserting its internal world into the provided world.
///
/// The `into` World will contain all nodes of the SceneGraph. You could iterate through the
/// SceneGraph manually if you'd like. The root entity has a [`SceneNodeRoot`] flag component,
/// and a Transform component. The children nodes have a [`SceneNodeFlag`] component and a
/// Transform component. The transforms of the children will be local, you must find its world
/// transform by traversing up the hierarchy of the scene manually with the `ChildOf` relation.
///
/// Returns: the Entity of the root node in the provided world.
pub fn into_world(mut self, into: &mut World) -> Entity {
// first insert the root entity into the World.
let v = self.world.view_one::<&Transform>(self.root_node.entity());
let pos = *v.get().unwrap();
let new_root = into.spawn((pos, SceneNodeRoot));
// now process the children of the root node.
Self::traverse_inserting_into(&mut self.world, self.root_node.entity(), new_root, into);
new_root
}
/// Recursively traverse the `from` world, starting at `node_en`, inserting the
/// children entity into the world.
///
/// Parameters:
/// * `scene_world` - The world that the SceneGraph exists in
/// * `scene_en` - The entity of the parent entity inside of the `scene_world`.
/// * `parent_en` - The entity of the parent entity inside of the `into` world.
/// * `into` - The world to insert the SceneGraph world into.
fn traverse_inserting_into(scene_world: &mut World, scene_en: Entity, parent_en: Entity, into: &mut World) {
let v = scene_world.view::<(Entities, &Transform)>()
.relates_to::<ChildOf>(scene_en);
// unfortunately, the borrow checker exists, and wasn't happy that `scene_world` was
// immutably borrowed with the view (v), and being mutably borrowed in the
// recursive call.
let mut child_entities = VecDeque::new();
for ((child_scene_en, pos), _rel) in v.iter() {
let into_en = into.spawn((*pos, SceneNodeFlag));
into.add_relation(into_en, ChildOf, parent_en);
child_entities.push_back((child_scene_en, into_en));
}
while let Some((child_scene_en, into_en)) = child_entities.pop_front() {
Self::traverse_inserting_into(scene_world, child_scene_en, into_en, into);
}
}
/// Adds a node to the root node of the SceneGraph.
///
/// The spawned entity will have a `ChildOf` relation targeting the root node, the
/// `SceneNodeFlag` component is also added to the entity.
pub fn add_node<B: Bundle>(&mut self, local_transform: Transform, bundle: B) -> SceneNode {
let node = self.root_node.clone();
self.add_node_under(&node, local_transform, bundle)
}
/// Add a node under a parent node.
///
/// The spawned entity will have a `ChildOf` relation targeting the provided parent node,
/// the `SceneNodeFlag` component is also added to the entity.
pub fn add_node_under<B: Bundle>(&mut self, parent: &SceneNode, local_transform: Transform, bundle: B) -> SceneNode {
world_add_child_node(&mut self.world, parent, local_transform, bundle)
}
/// Traverses down the SceneGraph, calling `callback` with each SceneNode and its world transform.
///
/// The traversal does not include the root scene node.
pub fn traverse_down<F>(&self, mut callback: F)
where
F: FnMut(&SceneNode, Transform),
{
self.traverse_down_from(self.root_node.clone(), &mut callback);
}
/// Traverses down the SceneGraph from a starting node, calling `callback` with each
/// SceneNode and its world transform.
fn traverse_down_from<F>(&self, start: SceneNode, callback: &mut F)
where
F: FnMut(&SceneNode, Transform),
{
let v = self.world.view::<(Entities, &Transform)>()
.relates_to::<ChildOf>(start.entity());
for ((e, _), _rel) in v.iter() {
let node = SceneNode::new(Some(start.entity()), e);
let world_pos = node.world_transform(self);
callback(&node, world_pos);
self.traverse_down_from(node, callback);
}
}
}
/// Add a node under a parent node.
///
/// The spawned entity will have a `ChildOf` relation targeting the provided parent node,
/// the `SceneNodeFlag` component is also added to the entity.
pub(crate) fn world_add_child_node<B: Bundle>(world: &mut World, parent: &SceneNode, local_transform: Transform, bundle: B) -> SceneNode {
let e = world.spawn(bundle);
world.insert(e, (SceneNodeFlag, local_transform));
world.add_relation(e, ChildOf, parent.entity());
SceneNode::new(Some(parent.entity()), e)
}
#[cfg(test)]
pub mod tests {
use lyra_ecs::{query::Entities, relation::ChildOf, Component, World};
use lyra_math::{Transform, Vec3};
use crate::{lyra_engine, SceneGraph, SceneNodeRoot};
#[derive(Component)]
pub struct FakeMesh;
#[test]
fn single_node_hierarchy() {
let mut scene = SceneGraph::new();
let a = scene.add_node(Transform::from_translation(Vec3::new(10.0, 10.0, 10.0)), FakeMesh);
assert!(a.parent(&scene).unwrap() == scene.root_node);
}
#[test]
fn double_node_hierarchy() {
let mut scene = SceneGraph::new();
let a = scene.add_node(Transform::from_translation(Vec3::new(10.0, 10.0, 10.0)), FakeMesh);
assert!(a.parent(&scene).unwrap() == scene.root_node);
let b = a.add_node(&mut scene, Transform::from_translation(Vec3::new(50.0, 50.0, 50.0)), FakeMesh);
assert!(b.parent(&scene).unwrap() == a);
}
#[test]
fn traverse_down() {
let v2s = vec![Vec3::new(10.0, 10.0, 10.0), Vec3::new(50.0, 50.0, 50.0)];
let mut scene = SceneGraph::new();
let a = scene.add_node(Transform::from_translation(v2s[0]), FakeMesh);
assert!(a.parent(&scene).unwrap() == scene.root_node);
let b = a.add_node(&mut scene, Transform::from_translation(v2s[1]), FakeMesh);
assert!(b.parent(&scene).unwrap() == a);
let mut idx = 0;
scene.traverse_down(|_e, pos| {
if idx == 0 {
assert_eq!(pos, Transform::from_translation(v2s[idx]));
} else if idx == 1 {
let t = v2s.iter().sum();
assert_eq!(pos, Transform::from_translation(t));
}
idx += 1;
});
}
#[test]
fn inserting_and_from_world() {
let v2s = vec![Vec3::new(10.0, 10.0, 10.0), Vec3::new(50.0, 50.0, 50.0)];
let mut scene = SceneGraph::new();
let a = scene.add_node(Transform::from_translation(v2s[0]), FakeMesh);
assert!(a.parent(&scene).unwrap() == scene.root_node);
let b = a.add_node(&mut scene, Transform::from_translation(v2s[1]), FakeMesh);
assert!(b.parent(&scene).unwrap() == a);
let mut other_world = World::new();
let root = scene.into_world(&mut other_world);
// check all of the entities inside of the World
let (root_pos, _) = other_world.view_one::<(&Transform, &SceneNodeRoot)>(root).get().unwrap();
assert_eq!(*root_pos, Transform::from_xyz(0.0, 0.0, 0.0));
let ((child_en, child_pos), _) = other_world.view::<(Entities, &Transform)>()
.relates_to::<ChildOf>(root).iter().next().unwrap();
assert_eq!(*child_pos, Transform::from_translation(v2s[0]));
let ((_, childchild_pos), _) = other_world.view::<(Entities, &Transform)>()
.relates_to::<ChildOf>(child_en).iter().next().unwrap();
assert_eq!(*childchild_pos, Transform::from_translation(v2s[1]));
drop(root_pos);
drop(child_pos);
drop(childchild_pos);
// Now get the SceneGraph inside the World and use the nice utility tools to traverse it.
let scene = SceneGraph::from_world(&mut other_world, root)
.expect("Failed to get SceneGraph from World!");
let mut idx = 0;
scene.traverse_down(|_e, pos| {
if idx == 0 {
assert_eq!(pos, Transform::from_translation(v2s[idx]));
} else if idx == 1 {
let t = v2s.iter().sum();
assert_eq!(pos, Transform::from_translation(t));
}
idx += 1;
});
}
}

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lyra-scene/src/node.rs Normal file
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use lyra_ecs::{query::Entities, relation::{ChildOf, RelationOriginComponent}, Bundle, Entity};
use lyra_math::Transform;
use crate::SceneGraph;
#[derive(Clone, PartialEq, Eq)]
pub struct SceneNode {
//world: WorldLock,
parent: Option<Entity>,
entity: Entity
}
impl SceneNode {
pub fn new(parent: Option<Entity>, entity: Entity) -> Self {
Self {
parent,
entity,
}
}
/// If this node has a parent, retrieves the parent node from the SceneGraph.
pub fn parent(&self, graph: &SceneGraph) -> Option<SceneNode> {
if let Some(parent) = self.parent {
let v = graph.world.view_one::<&RelationOriginComponent<ChildOf>>(parent);
let p_parent = if let Some(pp) = v.get() {
Some(pp.target())
} else { None };
Some(SceneNode::new(p_parent, parent))
} else {
None
}
}
pub fn parent_entity(&self) -> Option<Entity> {
self.parent
}
pub fn children(&self, graph: &SceneGraph) -> Vec<SceneNode> {
let v = graph.world.view::<Entities>()
.relates_to::<ChildOf>(self.entity);
v.into_iter().map(|(e, _)| SceneNode::new(Some(self.entity), e)).collect()
}
pub fn entity(&self) -> Entity {
self.entity
}
/// Add a child node to this node.
///
/// The spawned entity backing the scene node will have a `ChildOf` relation targeting
/// the provided parent node, the `SceneNodeFlag` component is also added to the entity.
pub fn add_node<B: Bundle>(&self, graph: &mut SceneGraph, local_transform: Transform, bundle: B) -> SceneNode {
graph.add_node_under(self, local_transform, bundle)
}
pub fn local_transform(&self, graph: &SceneGraph) -> Transform {
let v = graph.world.view_one::<&Transform>(self.entity);
let t = v.get().expect("Somehow the SceneNode is missing its Transform!");
t.clone()
}
/// Retrieves the world transform of the Node.
///
/// This traverses up the SceneGraph from this node.
pub fn world_transform(&self, graph: &SceneGraph) -> Transform {
match self.parent(graph) {
Some(parent) => {
let pt = parent.world_transform(graph);
pt + self.local_transform(graph)
},
None => {
self.local_transform(graph)
}
}
}
}
#[cfg(test)]
mod tests {
use lyra_math::{Transform, Vec3};
use crate::{tests::FakeMesh, SceneGraph};
#[test]
fn node_world_transform() {
let mut scene = SceneGraph::new();
let a = scene.add_node(Transform::from_translation(Vec3::new(10.0, 10.0, 10.0)), FakeMesh);
assert!(a.parent(&scene).unwrap() == scene.root_node);
let b = a.add_node(&mut scene, Transform::from_translation(Vec3::new(50.0, 50.0, 50.0)), FakeMesh);
assert!(b.parent(&scene).unwrap() == a);
let wrld_tran = b.world_transform(&scene);
assert_eq!(wrld_tran, Transform::from_translation(Vec3::new(60.0, 60.0, 60.0)));
}
}