## Objective
There's no general error for when an entity doesn't exist, and some
methods are going to need one when they get Resultified. The closest
thing is `EntityFetchError`, but that error has a slightly more specific
purpose.
## Solution
- Added `EntityDoesNotExistError`.
- Contains `Entity` and `EntityDoesNotExistDetails`.
- Changed `EntityFetchError` and `QueryEntityError`:
- Changed `NoSuchEntity` variant to wrap `EntityDoesNotExistError` and
renamed the variant to `EntityDoesNotExist`.
- Renamed `EntityFetchError` to `EntityMutableFetchError` to make its
purpose clearer.
- Renamed `TryDespawnError` to `EntityDespawnError` to make it more
general.
- Changed `World::inspect_entity` to return `Result<[ok],
EntityDoesNotExistError>` instead of panicking.
- Changed `World::get_entity` and `WorldEntityFetch::fetch_ref` to
return `Result<[ok], EntityDoesNotExistError>` instead of `Result<[ok],
Entity>`.
- Changed `UnsafeWorldCell::get_entity` to return
`Result<UnsafeEntityCell, EntityDoesNotExistError>` instead of
`Option<UnsafeEntityCell>`.
## Migration Guide
- `World::inspect_entity` now returns `Result<impl Iterator<Item =
&ComponentInfo>, EntityDoesNotExistError>` instead of `impl
Iterator<Item = &ComponentInfo>`.
- `World::get_entity` now returns `EntityDoesNotExistError` as an error
instead of `Entity`. You can still access the entity's ID through the
error's `entity` field.
- `UnsafeWorldCell::get_entity` now returns `Result<UnsafeEntityCell,
EntityDoesNotExistError>` instead of `Option<UnsafeEntityCell>`.
# Objective
Simplify the API surface by removing duplicated functionality between
`Query` and `QueryState`.
Reduce the amount of `unsafe` code required in `QueryState`.
This is a follow-up to #15858.
## Solution
Move implementations of `Query` methods from `QueryState` to `Query`.
Instead of the original methods being on `QueryState`, with `Query`
methods calling them by passing the individual parameters, the original
methods are now on `Query`, with `QueryState` methods calling them by
constructing a `Query`.
This also adds two `_inner` methods that were missed in #15858:
`iter_many_unique_inner` and `single_inner`.
One goal here is to be able to deprecate and eventually remove many of
the methods on `QueryState`, reducing the overall API surface. (I
expected to do that in this PR, but this change was large enough on its
own!) Now that the `QueryState` methods each consist of a simple
expression like `self.query(world).get_inner(entity)`, a future PR can
deprecate some or all of them with simple migration instructions.
The other goal is to reduce the amount of `unsafe` code. The current
implementation of a read-only method like `QueryState::get` directly
calls the `unsafe fn get_unchecked_manual` and needs to repeat the proof
that `&World` has enough access. With this change, `QueryState::get` is
entirely safe code, with the proof that `&World` has enough access done
by the `query()` method and shared across all read-only operations.
## Future Work
The next step will be to mark the `QueryState` methods as
`#[deprecated]` and migrate callers to the methods on `Query`.
# Objective
Support accessing resources using reflection when using
`FilteredResources` in a dynamic system. This is similar to how
components can be queried using reflection when using
`FilteredEntityRef|Mut`.
## Solution
Change `ReflectResource` from taking `&World` and `&mut World` to taking
`impl Into<FilteredResources>` and `impl Into<FilteredResourcesMut>`,
similar to how `ReflectComponent` takes `impl Into<FilteredEntityRef>`
and `impl Into<FilteredEntityMut>`. There are `From` impls that ensure
code passing `&World` and `&mut World` continues to work as before.
## Migration Guide
If you are manually creating a `ReflectComponentFns` struct, the
`reflect` function now takes `FilteredResources` instead `&World`, and
there is a new `reflect_mut` function that takes `FilteredResourcesMut`.
# Objective
Continuation of #16547.
We do not yet have parallel versions of `par_iter_many` and
`par_iter_many_unique`. It is currently very painful to try and use
parallel iteration over entity lists. Even if a list is not long, each
operation might still be very expensive, and worth parallelizing.
Plus, it has been requested several times!
## Solution
Once again, we implement what we lack!
These parallel iterators collect their input entity list into a
`Vec`/`UniqueEntityVec`, then chunk that over the available threads,
inspired by the original `par_iter`.
Since no order guarantee is given to the caller, we could sort the input
list according to `EntityLocation`, but that would likely only be worth
it for very large entity lists.
There is some duplication which could likely be improved, but I'd like
to leave that for a follow-up.
## Testing
The doc tests on `for_each_init` of `QueryParManyIter` and
`QueryParManyUniqueIter`.
# Objective
Fix unsoundness introduced by #15858. `QueryLens::query()` would hand
out a `Query` with the full `'w` lifetime, and the new `_inner` methods
would let the results outlive the `Query`. This could be used to create
aliasing mutable references, like
```rust
fn bad<'w>(mut lens: QueryLens<'w, EntityMut>, entity: Entity) {
let one: EntityMut<'w> = lens.query().get_inner(entity).unwrap();
let two: EntityMut<'w> = lens.query().get_inner(entity).unwrap();
assert!(one.entity() == two.entity());
}
```
Fixes#17693
## Solution
Restrict the `'world` lifetime in the `Query` returned by
`QueryLens::query()` to `'_`, the lifetime of the borrow of the
`QueryLens`.
The model here is that `Query<'w, 's, D, F>` and `QueryLens<'w, D, F>`
have permission to access their components for the lifetime `'w`. So
going from `&'a mut QueryLens<'w>` to `Query<'w, 'a>` would borrow the
permission only for the `'a` lifetime, but incorrectly give it out for
the full `'w` lifetime.
To handle any cases where users were calling `get_inner()` or
`iter_inner()` on the `Query` and expecting the full `'w` lifetime, we
introduce a new `QueryLens::query_inner()` method. This is only valid
for `ReadOnlyQueryData`, so it may safely hand out a copy of the
permission for the full `'w` lifetime. Since `get_inner()` and
`iter_inner()` were only valid on `ReadOnlyQueryData` prior to #15858,
that should cover any uses that relied on the longer lifetime.
## Migration Guide
Users of `QueryLens::query()` who were calling `get_inner()` or
`iter_inner()` will need to replace the call with
`QueryLens::query_inner()`.
This commit builds on top of the work done in #16589 and #17051, by
adding support for fallible observer systems.
As with the previous work, the actual results of the observer system are
suppressed for now, but the intention is to provide a way to handle
errors in a global way.
Until then, you can use a `PipeSystem` to manually handle results.
---------
Signed-off-by: Jean Mertz <git@jeanmertz.com>
# Objective
Restore the behavior of `Query::get_many` prior to #15858.
When passed duplicate `Entity`s, `get_many` is supposed to return
results for all of them, since read-only queries don't alias. However,
#15858 merged the implementation with `get_many_mut` and caused it to
return `QueryEntityError::AliasedMutability`.
## Solution
Introduce a new `Query::get_many_readonly` method that consumes the
`Query` like `get_many_inner`, but that is constrained to `D:
ReadOnlyQueryData` so that it can skip the aliasing check. Implement
`Query::get_many` in terms of that new method. Add a test, and a comment
explaining why it doesn't match the pattern of the other `&self`
methods.
# Objective
Eliminate the need to write `cfg(feature = "track_location")` every time
one uses an API that may use location tracking. It's verbose, and a
little intimidating. And it requires code outside of `bevy_ecs` that
wants to use location tracking needs to either unconditionally enable
the feature, or include conditional compilation of its own. It would be
good for users to be able to log locations when they are available
without needing to add feature flags to their own crates.
Reduce the number of cases where code compiles with the `track_location`
feature enabled, but not with it disabled, or vice versa. It can be hard
to remember to test it both ways!
Remove the need to store a `None` in `HookContext` when the
`track_location` feature is disabled.
## Solution
Create an `MaybeLocation<T>` type that contains a `T` if the
`track_location` feature is enabled, and is a ZST if it is not. The
overall API is similar to `Option`, but whether the value is `Some` or
`None` is set at compile time and is the same for all values.
Default `T` to `&'static Location<'static>`, since that is the most
common case.
Remove all `cfg(feature = "track_location")` blocks outside of the
implementation of that type, and instead call methods on it.
When `track_location` is disabled, `MaybeLocation` is a ZST and all
methods are `#[inline]` and empty, so they should be entirely removed by
the compiler. But the code will still be visible to the compiler and
checked, so if it compiles with the feature disabled then it should also
compile with it enabled, and vice versa.
## Open Questions
Where should these types live? I put them in `change_detection` because
that's where the existing `MaybeLocation` types were, but we now use
these outside of change detection.
While I believe that the compiler should be able to remove all of these
calls, I have not actually tested anything. If we want to take this
approach, what testing is required to ensure it doesn't impact
performance?
## Migration Guide
Methods like `Ref::changed_by()` that return a `&'static
Location<'static>` will now be available even when the `track_location`
feature is disabled, but they will return a new `MaybeLocation` type.
`MaybeLocation` wraps a `&'static Location<'static>` when the feature is
enabled, and is a ZST when the feature is disabled.
Existing code that needs a `&Location` can call `into_option().unwrap()`
to recover it. Many trait impls are forwarded, so if you only need
`Display` then no changes will be necessary.
If that code was conditionally compiled, you may instead want to use the
methods on `MaybeLocation` to remove the need for conditional
compilation.
Code that constructs a `Ref`, `Mut`, `Res`, or `ResMut` will now need to
provide location information unconditionally. If you are creating them
from existing Bevy types, you can obtain a `MaybeLocation` from methods
like `Table::get_changed_by_slice_for()` or
`ComponentSparseSet::get_with_ticks`. Otherwise, you will need to store
a `MaybeLocation` next to your data and use methods like `as_ref()` or
`as_mut()` to obtain wrapped references.
## Objective
A major critique of Bevy at the moment is how boilerplatey it is to
compose (and read) entity hierarchies:
```rust
commands
.spawn(Foo)
.with_children(|p| {
p.spawn(Bar).with_children(|p| {
p.spawn(Baz);
});
p.spawn(Bar).with_children(|p| {
p.spawn(Baz);
});
});
```
There is also currently no good way to statically define and return an
entity hierarchy from a function. Instead, people often do this
"internally" with a Commands function that returns nothing, making it
impossible to spawn the hierarchy in other cases (direct World spawns,
ChildSpawner, etc).
Additionally, because this style of API results in creating the
hierarchy bits _after_ the initial spawn of a bundle, it causes ECS
archetype changes (and often expensive table moves).
Because children are initialized after the fact, we also can't count
them to pre-allocate space. This means each time a child inserts itself,
it has a high chance of overflowing the currently allocated capacity in
the `RelationshipTarget` collection, causing literal worst-case
reallocations.
We can do better!
## Solution
The Bundle trait has been extended to support an optional
`BundleEffect`. This is applied directly to World immediately _after_
the Bundle has fully inserted. Note that this is
[intentionally](https://github.com/bevyengine/bevy/discussions/16920)
_not done via a deferred Command_, which would require repeatedly
copying each remaining subtree of the hierarchy to a new command as we
walk down the tree (_not_ good performance).
This allows us to implement the new `SpawnRelated` trait for all
`RelationshipTarget` impls, which looks like this in practice:
```rust
world.spawn((
Foo,
Children::spawn((
Spawn((
Bar,
Children::spawn(Spawn(Baz)),
)),
Spawn((
Bar,
Children::spawn(Spawn(Baz)),
)),
))
))
```
`Children::spawn` returns `SpawnRelatedBundle<Children, L:
SpawnableList>`, which is a `Bundle` that inserts `Children`
(preallocated to the size of the `SpawnableList::size_hint()`).
`Spawn<B: Bundle>(pub B)` implements `SpawnableList` with a size of 1.
`SpawnableList` is also implemented for tuples of `SpawnableList` (same
general pattern as the Bundle impl).
There are currently three built-in `SpawnableList` implementations:
```rust
world.spawn((
Foo,
Children::spawn((
Spawn(Name::new("Child1")),
SpawnIter(["Child2", "Child3"].into_iter().map(Name::new),
SpawnWith(|parent: &mut ChildSpawner| {
parent.spawn(Name::new("Child4"));
parent.spawn(Name::new("Child5"));
})
)),
))
```
We get the benefits of "structured init", but we have nice flexibility
where it is required!
Some readers' first instinct might be to try to remove the need for the
`Spawn` wrapper. This is impossible in the Rust type system, as a tuple
of "child Bundles to be spawned" and a "tuple of Components to be added
via a single Bundle" is ambiguous in the Rust type system. There are two
ways to resolve that ambiguity:
1. By adding support for variadics to the Rust type system (removing the
need for nested bundles). This is out of scope for this PR :)
2. Using wrapper types to resolve the ambiguity (this is what I did in
this PR).
For the single-entity spawn cases, `Children::spawn_one` does also
exist, which removes the need for the wrapper:
```rust
world.spawn((
Foo,
Children::spawn_one(Bar),
))
```
## This works for all Relationships
This API isn't just for `Children` / `ChildOf` relationships. It works
for any relationship type, and they can be mixed and matched!
```rust
world.spawn((
Foo,
Observers::spawn((
Spawn(Observer::new(|trigger: Trigger<FuseLit>| {})),
Spawn(Observer::new(|trigger: Trigger<Exploded>| {})),
)),
OwnerOf::spawn(Spawn(Bar))
Children::spawn(Spawn(Baz))
))
```
## Macros
While `Spawn` is necessary to satisfy the type system, we _can_ remove
the need to express it via macros. The example above can be expressed
more succinctly using the new `children![X]` macro, which internally
produces `Children::spawn(Spawn(X))`:
```rust
world.spawn((
Foo,
children![
(
Bar,
children![Baz],
),
(
Bar,
children![Baz],
),
]
))
```
There is also a `related!` macro, which is a generic version of the
`children!` macro that supports any relationship type:
```rust
world.spawn((
Foo,
related!(Children[
(
Bar,
related!(Children[Baz]),
),
(
Bar,
related!(Children[Baz]),
),
])
))
```
## Returning Hierarchies from Functions
Thanks to these changes, the following pattern is now possible:
```rust
fn button(text: &str, color: Color) -> impl Bundle {
(
Node {
width: Val::Px(300.),
height: Val::Px(100.),
..default()
},
BackgroundColor(color),
children![
Text::new(text),
]
)
}
fn ui() -> impl Bundle {
(
Node {
width: Val::Percent(100.0),
height: Val::Percent(100.0),
..default(),
},
children![
button("hello", BLUE),
button("world", RED),
]
)
}
// spawn from a system
fn system(mut commands: Commands) {
commands.spawn(ui());
}
// spawn directly on World
world.spawn(ui());
```
## Additional Changes and Notes
* `Bundle::from_components` has been split out into
`BundleFromComponents::from_components`, enabling us to implement
`Bundle` for types that cannot be "taken" from the ECS (such as the new
`SpawnRelatedBundle`).
* The `NoBundleEffect` trait (which implements `BundleEffect`) is
implemented for empty tuples (and tuples of empty tuples), which allows
us to constrain APIs to only accept bundles that do not have effects.
This is critical because the current batch spawn APIs cannot efficiently
apply BundleEffects in their current form (as doing so in-place could
invalidate the cached raw pointers). We could consider allocating a
buffer of the effects to be applied later, but that does have
performance implications that could offset the balance and value of the
batched APIs (and would likely require some refactors to the underlying
code). I've decided to be conservative here. We can consider relaxing
that requirement on those APIs later, but that should be done in a
followup imo.
* I've ported a few examples to illustrate real-world usage. I think in
a followup we should port all examples to the `children!` form whenever
possible (and for cases that require things like SpawnIter, use the raw
APIs).
* Some may ask "why not use the `Relationship` to spawn (ex:
`ChildOf::spawn(Foo)`) instead of the `RelationshipTarget` (ex:
`Children::spawn(Spawn(Foo))`)?". That _would_ allow us to remove the
`Spawn` wrapper. I've explicitly chosen to disallow this pattern.
`Bundle::Effect` has the ability to create _significant_ weirdness.
Things in `Bundle` position look like components. For example
`world.spawn((Foo, ChildOf::spawn(Bar)))` _looks and reads_ like Foo is
a child of Bar. `ChildOf` is in Foo's "component position" but it is not
a component on Foo. This is a huge problem. Now that `Bundle::Effect`
exists, we should be _very_ principled about keeping the "weird and
unintuitive behavior" to a minimum. Things that read like components
_should be the components they appear to be".
## Remaining Work
* The macros are currently trivially implemented using macro_rules and
are currently limited to the max tuple length. They will require a
proc_macro implementation to work around the tuple length limit.
## Next Steps
* Port the remaining examples to use `children!` where possible and raw
`Spawn` / `SpawnIter` / `SpawnWith` where the flexibility of the raw API
is required.
## Migration Guide
Existing spawn patterns will continue to work as expected.
Manual Bundle implementations now require a `BundleEffect` associated
type. Exisiting bundles would have no bundle effect, so use `()`.
Additionally `Bundle::from_components` has been moved to the new
`BundleFromComponents` trait.
```rust
// Before
unsafe impl Bundle for X {
unsafe fn from_components<T, F>(ctx: &mut T, func: &mut F) -> Self {
}
/* remaining bundle impl here */
}
// After
unsafe impl Bundle for X {
type Effect = ();
/* remaining bundle impl here */
}
unsafe impl BundleFromComponents for X {
unsafe fn from_components<T, F>(ctx: &mut T, func: &mut F) -> Self {
}
}
```
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com>
Co-authored-by: Emerson Coskey <emerson@coskey.dev>
# Objective
Solves https://github.com/bevyengine/bevy/issues/17747.
## Solution
- Adds an example for creating a default value for Local.
## Testing
- Example code compiles and passes assertions.
This pr uses the `extern crate self as` trick to make proc macros behave
the same way inside and outside bevy.
# Objective
- Removes noise introduced by `crate as` in the whole bevy repo.
- Fixes#17004.
- Hardens proc macro path resolution.
## TODO
- [x] `BevyManifest` needs cleanup.
- [x] Cleanup remaining `crate as`.
- [x] Add proper integration tests to the ci.
## Notes
- `cargo-manifest-proc-macros` is written by me and based/inspired by
the old `BevyManifest` implementation and
[`bkchr/proc-macro-crate`](https://github.com/bkchr/proc-macro-crate).
- What do you think about the new integration test machinery I added to
the `ci`?
More and better integration tests can be added at a later stage.
The goal of these integration tests is to simulate an actual separate
crate that uses bevy. Ideally they would lightly touch all bevy crates.
## Testing
- Needs RA test
- Needs testing from other users
- Others need to run at least `cargo run -p ci integration-test` and
verify that they work.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Fixes#17535
Bevy's approach to handling "entity mapping" during spawning and cloning
needs some work. The addition of
[Relations](https://github.com/bevyengine/bevy/pull/17398) both
[introduced a new "duplicate entities" bug when spawning scenes in the
scene system](#17535) and made the weaknesses of the current mapping
system exceedingly clear:
1. Entity mapping requires _a ton_ of boilerplate (implement or derive
VisitEntities and VisitEntitesMut, then register / reflect MapEntities).
Knowing the incantation is challenging and if you forget to do it in
part or in whole, spawning subtly breaks.
2. Entity mapping a spawned component in scenes incurs unnecessary
overhead: look up ReflectMapEntities, create a _brand new temporary
instance_ of the component using FromReflect, map the entities in that
instance, and then apply that on top of the actual component using
reflection. We can do much better.
Additionally, while our new [Entity cloning
system](https://github.com/bevyengine/bevy/pull/16132) is already pretty
great, it has some areas we can make better:
* It doesn't expose semantic info about the clone (ex: ignore or "clone
empty"), meaning we can't key off of that in places where it would be
useful, such as scene spawning. Rather than duplicating this info across
contexts, I think it makes more sense to add that info to the clone
system, especially given that we'd like to use cloning code in some of
our spawning scenarios.
* EntityCloner is currently built in a way that prioritizes a single
entity clone
* EntityCloner's recursive cloning is built to be done "inside out" in a
parallel context (queue commands that each have a clone of
EntityCloner). By making EntityCloner the orchestrator of the clone we
can remove internal arcs, improve the clarity of the code, make
EntityCloner mutable again, and simplify the builder code.
* EntityCloner does not currently take into account entity mapping. This
is necessary to do true "bullet proof" cloning, would allow us to unify
the per-component scene spawning and cloning UX, and ultimately would
allow us to use EntityCloner in place of raw reflection for scenes like
`Scene(World)` (which would give us a nice performance boost: fewer
archetype moves, less reflection overhead).
## Solution
### Improved Entity Mapping
First, components now have first-class "entity visiting and mapping"
behavior:
```rust
#[derive(Component, Reflect)]
#[reflect(Component)]
struct Inventory {
size: usize,
#[entities]
items: Vec<Entity>,
}
```
Any field with the `#[entities]` annotation will be viewable and
mappable when cloning and spawning scenes.
Compare that to what was required before!
```rust
#[derive(Component, Reflect, VisitEntities, VisitEntitiesMut)]
#[reflect(Component, MapEntities)]
struct Inventory {
#[visit_entities(ignore)]
size: usize,
items: Vec<Entity>,
}
```
Additionally, for relationships `#[entities]` is implied, meaning this
"just works" in scenes and cloning:
```rust
#[derive(Component, Reflect)]
#[relationship(relationship_target = Children)]
#[reflect(Component)]
struct ChildOf(pub Entity);
```
Note that Component _does not_ implement `VisitEntities` directly.
Instead, it has `Component::visit_entities` and
`Component::visit_entities_mut` methods. This is for a few reasons:
1. We cannot implement `VisitEntities for C: Component` because that
would conflict with our impl of VisitEntities for anything that
implements `IntoIterator<Item=Entity>`. Preserving that impl is more
important from a UX perspective.
2. We should not implement `Component: VisitEntities` VisitEntities in
the Component derive, as that would increase the burden of manual
Component trait implementors.
3. Making VisitEntitiesMut directly callable for components would make
it easy to invalidate invariants defined by a component author. By
putting it in the `Component` impl, we can make it harder to call
naturally / unavailable to autocomplete using `fn
visit_entities_mut(this: &mut Self, ...)`.
`ReflectComponent::apply_or_insert` is now
`ReflectComponent::apply_or_insert_mapped`. By moving mapping inside
this impl, we remove the need to go through the reflection system to do
entity mapping, meaning we no longer need to create a clone of the
target component, map the entities in that component, and patch those
values on top. This will make spawning mapped entities _much_ faster
(The default `Component::visit_entities_mut` impl is an inlined empty
function, so it will incur no overhead for unmapped entities).
### The Bug Fix
To solve #17535, spawning code now skips entities with the new
`ComponentCloneBehavior::Ignore` and
`ComponentCloneBehavior::RelationshipTarget` variants (note
RelationshipTarget is a temporary "workaround" variant that allows
scenes to skip these components. This is a temporary workaround that can
be removed as these cases should _really_ be using EntityCloner logic,
which should be done in a followup PR. When that is done,
`ComponentCloneBehavior::RelationshipTarget` can be merged into the
normal `ComponentCloneBehavior::Custom`).
### Improved Cloning
* `Option<ComponentCloneHandler>` has been replaced by
`ComponentCloneBehavior`, which encodes additional intent and context
(ex: `Default`, `Ignore`, `Custom`, `RelationshipTarget` (this last one
is temporary)).
* Global per-world entity cloning configuration has been removed. This
felt overly complicated, increased our API surface, and felt too
generic. Each clone context can have different requirements (ex: what a
user wants in a specific system, what a scene spawner wants, etc). I'd
prefer to see how far context-specific EntityCloners get us first.
* EntityCloner's internals have been reworked to remove Arcs and make it
mutable.
* EntityCloner is now directly stored on EntityClonerBuilder,
simplifying the code somewhat
* EntityCloner's "bundle scratch" pattern has been moved into the new
BundleScratch type, improving its usability and making it usable in
other contexts (such as future cross-world cloning code). Currently this
is still private, but with some higher level safe APIs it could be used
externally for making dynamic bundles
* EntityCloner's recursive cloning behavior has been "externalized". It
is now responsible for orchestrating recursive clones, meaning it no
longer needs to be sharable/clone-able across threads / read-only.
* EntityCloner now does entity mapping during clones, like scenes do.
This gives behavior parity and also makes it more generically useful.
* `RelatonshipTarget::RECURSIVE_SPAWN` is now
`RelationshipTarget::LINKED_SPAWN`, and this field is used when cloning
relationship targets to determine if cloning should happen recursively.
The new `LINKED_SPAWN` term was picked to make it more generically
applicable across spawning and cloning scenarios.
## Next Steps
* I think we should adapt EntityCloner to support cross world cloning. I
think this PR helps set the stage for that by making the internals
slightly more generalized. We could have a CrossWorldEntityCloner that
reuses a lot of this infrastructure.
* Once we support cross world cloning, we should use EntityCloner to
spawn `Scene(World)` scenes. This would yield significant performance
benefits (no archetype moves, less reflection overhead).
---------
Co-authored-by: eugineerd <70062110+eugineerd@users.noreply.github.com>
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
# Objective
Simplify and expand the API for `QueryState`.
`QueryState` has a lot of methods that mirror those on `Query`. These
are then multiplied by variants that take `&World`, `&mut World`, and
`UnsafeWorldCell`. In addition, many of them have `_manual` variants
that take `&QueryState` and avoid calling `update_archetypes()`. Not all
of the combinations exist, however, so some operations are not possible.
## Solution
Introduce methods to get a `Query` from a `QueryState`. That will reduce
duplication between the types, and ensure that the full `Query` API is
always available for `QueryState`.
Introduce methods on `Query` that consume the query to return types with
the full `'w` lifetime. This avoids issues with borrowing where things
like `query_state.query(&world).get(entity)` don't work because they
borrow from the temporary `Query`.
Finally, implement `Copy` for read-only `Query`s. `get_inner` and
`iter_inner` currently take `&self`, so changing them to consume `self`
would be a breaking change. By making `Query: Copy`, they can consume a
copy of `self` and continue to work.
The consuming methods also let us simplify the implementation of methods
on `Query`, by doing `fn foo(&self) { self.as_readonly().foo_inner() }`
and `fn foo_mut(&mut self) { self.reborrow().foo_inner() }`. That
structure makes it more difficult to accidentally extend lifetimes,
since the safe `as_readonly()` and `reborrow()` methods shrink them
appropriately. The optimizer is able to see that they are both identity
functions and inline them, so there should be no performance cost.
Note that this change would conflict with #15848. If `QueryState` is
stored as a `Cow`, then the consuming methods cannot be implemented, and
`Copy` cannot be implemented.
## Future Work
The next step is to mark the methods on `QueryState` as `#[deprecated]`,
and move the implementations into `Query`.
## Migration Guide
`Query::to_readonly` has been renamed to `Query::as_readonly`.
# Objective
While working on #17649, I found the docs for `WorldQuery` and the
related traits frustratingly vague.
## Solution
Clarify them and add some more tangible advice.
Also fix a copy-pasted typo in related comments.
---------
Co-authored-by: James O'Brien <james.obrien@drafly.net>
# Objective
Prevent unsound uses of `DeferredWorld` as a `SystemParam`. It is
currently unsound because it does not check for existing access, and
because it incorrectly registers filtered access.
## Solution
Have `DeferredWorld` panic if a previous parameter has conflicting
access.
Have `DeferredWorld` update `archetype_component_access` so that the
multi-threaded executor sees the access.
Fix `FilteredAccessSet::read_all()` and `write_all()` to correctly add a
`FilteredAccess` with no filter so that `Query` is able to detect the
conflicts.
Remove redundant `read_all()` call, since `write_all()` already declares
read access.
Remove unnecessary `set_has_deferred()` call, since `<DeferredWorld as
SystemParam>::apply_deferred()` does nothing. Previously we were
inserting unnecessary `apply_deferred` systems in the schedule.
## Testing
Added unit tests for systems where `DeferredWorld` conflicts with a
`Query` in the same system.
# Objective
We have default query filters now, but there is no first-party marker
for entity disabling yet
Fixes#17458
## Solution
Add the marker, cool recursive features and/or potential hook changes
should be follow up work
## Testing
Added a unit test to check that the new marker is enabled by default
This allows you to continue chaining method calls after calling
`EntityCommands::entry`:
```rust
commands
.entity(player.entity)
.entry::<Level>()
// Modify the component if it exists
.and_modify(|mut lvl| lvl.0 += 1)
// Otherwise insert a default value
.or_insert(Level(0))
// Return the EntityCommands for the entity
.entity()
// And continue chaining method calls
.insert(Name::new("Player"));
```
---------
Signed-off-by: Jean Mertz <git@jeanmertz.com>
# Objective
Fixes#14708
Also fixes some commands not updating tracked location.
## Solution
`ObserverTrigger` has a new `caller` field with the
`track_change_detection` feature;
hooks take an additional caller parameter (which is `Some(…)` or `None`
depending on the feature).
## Testing
See the new tests in `src/observer/mod.rs`
---
## Showcase
Observers now know from where they were triggered (if
`track_change_detection` is enabled):
```rust
world.observe(move |trigger: Trigger<OnAdd, Foo>| {
println!("Added Foo from {}", trigger.caller());
});
```
## Migration
- hooks now take an additional `Option<&'static Location>` argument
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
## Objective
Most `try` methods on `World` return a `Result`, but `try_despawn` and
`try_insert_batch` don't. Since Bevy's error handling is advancing,
these should be brought in line.
## Solution
- Added `TryDespawnError` and `TryInsertBatchError`.
- `try_despawn`, `try_insert_batch`, and `try_insert_batch_if_new` now
return their respective errors.
- Fixed slightly incorrect behavior in `try_insert_batch_with_caller`.
- The method was always meant to continue with the rest of the batch if
an entity was missing, but that only worked after the first entity; if
the first entity was missing, the method would exit early. This has been
resolved.
## Migration Guide
- `World::try_despawn` now returns a `Result` rather than a `bool`.
- `World::try_insert_batch` and `World::try_insert_batch_if_new` now
return a `Result` where they previously returned nothing.
# Objective
`bevy_ecs`'s `system` module is something of a grab bag, and *very*
large. This is particularly true for the `system_param` module, which is
more than 2k lines long!
While it could be defensible to put `Res` and `ResMut` there (lol no
they're in change_detection.rs, obviously), it doesn't make any sense to
put the `Resource` trait there. This is confusing to navigate (and
painful to work on and review).
## Solution
- Create a root level `bevy_ecs/resource.rs` module to mirror
`bevy_ecs/component.rs`
- move the `Resource` trait to that module
- move the `Resource` derive macro to that module as well (Rust really
likes when you pun on the names of the derive macro and trait and put
them in the same path)
- fix all of the imports
## Notes to reviewers
- We could probably move more stuff into here, but I wanted to keep this
PR as small as possible given the absurd level of import changes.
- This PR is ground work for my upcoming attempts to store resource data
on components (resources-as-entities). Splitting this code out will make
the work and review a bit easier, and is the sort of overdue refactor
that's good to do as part of more meaningful work.
## Testing
cargo build works!
## Migration Guide
`bevy_ecs::system::Resource` has been moved to
`bevy_ecs::resource::Resource`.
docs: enhance documentation in `query.rs` to clarify borrowing rules.
Please, let me know if you don't agree with the wording.. There is
always room for improvement.
Tested locally and it looks like this:
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
This adds support for one-to-many non-fragmenting relationships (with
planned paths for fragmenting and non-fragmenting many-to-many
relationships). "Non-fragmenting" means that entities with the same
relationship type, but different relationship targets, are not forced
into separate tables (which would cause "table fragmentation").
Functionally, this fills a similar niche as the current Parent/Children
system. The biggest differences are:
1. Relationships have simpler internals and significantly improved
performance and UX. Commands and specialized APIs are no longer
necessary to keep everything in sync. Just spawn entities with the
relationship components you want and everything "just works".
2. Relationships are generalized. Bevy can provide additional built in
relationships, and users can define their own.
**REQUEST TO REVIEWERS**: _please don't leave top level comments and
instead comment on specific lines of code. That way we can take
advantage of threaded discussions. Also dont leave comments simply
pointing out CI failures as I can read those just fine._
## Built on top of what we have
Relationships are implemented on top of the Bevy ECS features we already
have: components, immutability, and hooks. This makes them immediately
compatible with all of our existing (and future) APIs for querying,
spawning, removing, scenes, reflection, etc. The fewer specialized APIs
we need to build, maintain, and teach, the better.
## Why focus on one-to-many non-fragmenting first?
1. This allows us to improve Parent/Children relationships immediately,
in a way that is reasonably uncontroversial. Switching our hierarchy to
fragmenting relationships would have significant performance
implications. ~~Flecs is heavily considering a switch to non-fragmenting
relations after careful considerations of the performance tradeoffs.~~
_(Correction from @SanderMertens: Flecs is implementing non-fragmenting
storage specialized for asset hierarchies, where asset hierarchies are
many instances of small trees that have a well defined structure)_
2. Adding generalized one-to-many relationships is currently a priority
for the [Next Generation Scene / UI
effort](https://github.com/bevyengine/bevy/discussions/14437).
Specifically, we're interested in building reactions and observers on
top.
## The changes
This PR does the following:
1. Adds a generic one-to-many Relationship system
3. Ports the existing Parent/Children system to Relationships, which now
lives in `bevy_ecs::hierarchy`. The old `bevy_hierarchy` crate has been
removed.
4. Adds on_despawn component hooks
5. Relationships can opt-in to "despawn descendants" behavior, meaning
that the entire relationship hierarchy is despawned when
`entity.despawn()` is called. The built in Parent/Children hierarchies
enable this behavior, and `entity.despawn_recursive()` has been removed.
6. `world.spawn` now applies commands after spawning. This ensures that
relationship bookkeeping happens immediately and removes the need to
manually flush. This is in line with the equivalent behaviors recently
added to the other APIs (ex: insert).
7. Removes the ValidParentCheckPlugin (system-driven / poll based) in
favor of a `validate_parent_has_component` hook.
## Using Relationships
The `Relationship` trait looks like this:
```rust
pub trait Relationship: Component + Sized {
type RelationshipSources: RelationshipSources<Relationship = Self>;
fn get(&self) -> Entity;
fn from(entity: Entity) -> Self;
}
```
A relationship is a component that:
1. Is a simple wrapper over a "target" Entity.
2. Has a corresponding `RelationshipSources` component, which is a
simple wrapper over a collection of entities. Every "target entity"
targeted by a "source entity" with a `Relationship` has a
`RelationshipSources` component, which contains every "source entity"
that targets it.
For example, the `Parent` component (as it currently exists in Bevy) is
the `Relationship` component and the entity containing the Parent is the
"source entity". The entity _inside_ the `Parent(Entity)` component is
the "target entity". And that target entity has a `Children` component
(which implements `RelationshipSources`).
In practice, the Parent/Children relationship looks like this:
```rust
#[derive(Relationship)]
#[relationship(relationship_sources = Children)]
pub struct Parent(pub Entity);
#[derive(RelationshipSources)]
#[relationship_sources(relationship = Parent)]
pub struct Children(Vec<Entity>);
```
The Relationship and RelationshipSources derives automatically implement
Component with the relevant configuration (namely, the hooks necessary
to keep everything in sync).
The most direct way to add relationships is to spawn entities with
relationship components:
```rust
let a = world.spawn_empty().id();
let b = world.spawn(Parent(a)).id();
assert_eq!(world.entity(a).get::<Children>().unwrap(), &[b]);
```
There are also convenience APIs for spawning more than one entity with
the same relationship:
```rust
world.spawn_empty().with_related::<Children>(|s| {
s.spawn_empty();
s.spawn_empty();
})
```
The existing `with_children` API is now a simpler wrapper over
`with_related`. This makes this change largely non-breaking for existing
spawn patterns.
```rust
world.spawn_empty().with_children(|s| {
s.spawn_empty();
s.spawn_empty();
})
```
There are also other relationship APIs, such as `add_related` and
`despawn_related`.
## Automatic recursive despawn via the new on_despawn hook
`RelationshipSources` can opt-in to "despawn descendants" behavior,
which will despawn all related entities in the relationship hierarchy:
```rust
#[derive(RelationshipSources)]
#[relationship_sources(relationship = Parent, despawn_descendants)]
pub struct Children(Vec<Entity>);
```
This means that `entity.despawn_recursive()` is no longer required.
Instead, just use `entity.despawn()` and the relevant related entities
will also be despawned.
To despawn an entity _without_ despawning its parent/child descendants,
you should remove the `Children` component first, which will also remove
the related `Parent` components:
```rust
entity
.remove::<Children>()
.despawn()
```
This builds on the on_despawn hook introduced in this PR, which is fired
when an entity is despawned (before other hooks).
## Relationships are the source of truth
`Relationship` is the _single_ source of truth component.
`RelationshipSources` is merely a reflection of what all the
`Relationship` components say. By embracing this, we are able to
significantly improve the performance of the system as a whole. We can
rely on component lifecycles to protect us against duplicates, rather
than needing to scan at runtime to ensure entities don't already exist
(which results in quadratic runtime). A single source of truth gives us
constant-time inserts. This does mean that we cannot directly spawn
populated `Children` components (or directly add or remove entities from
those components). I personally think this is a worthwhile tradeoff,
both because it makes the performance much better _and_ because it means
theres exactly one way to do things (which is a philosophy we try to
employ for Bevy APIs).
As an aside: treating both sides of the relationship as "equivalent
source of truth relations" does enable building simple and flexible
many-to-many relationships. But this introduces an _inherent_ need to
scan (or hash) to protect against duplicates.
[`evergreen_relations`](https://github.com/EvergreenNest/evergreen_relations)
has a very nice implementation of the "symmetrical many-to-many"
approach. Unfortunately I think the performance issues inherent to that
approach make it a poor choice for Bevy's default relationship system.
## Followup Work
* Discuss renaming `Parent` to `ChildOf`. I refrained from doing that in
this PR to keep the diff reasonable, but I'm personally biased toward
this change (and using that naming pattern generally for relationships).
* [Improved spawning
ergonomics](https://github.com/bevyengine/bevy/discussions/16920)
* Consider adding relationship observers/triggers for "relationship
targets" whenever a source is added or removed. This would replace the
current "hierarchy events" system, which is unused upstream but may have
existing users downstream. I think triggers are the better fit for this
than a buffered event queue, and would prefer not to add that back.
* Fragmenting relations: My current idea hinges on the introduction of
"value components" (aka: components whose type _and_ value determines
their ComponentId, via something like Hashing / PartialEq). By labeling
a Relationship component such as `ChildOf(Entity)` as a "value
component", `ChildOf(e1)` and `ChildOf(e2)` would be considered
"different components". This makes the transition between fragmenting
and non-fragmenting a single flag, and everything else continues to work
as expected.
* Many-to-many support
* Non-fragmenting: We can expand Relationship to be a list of entities
instead of a single entity. I have largely already written the code for
this.
* Fragmenting: With the "value component" impl mentioned above, we get
many-to-many support "for free", as it would allow inserting multiple
copies of a Relationship component with different target entities.
Fixes#3742 (If this PR is merged, I think we should open more targeted
followup issues for the work above, with a fresh tracking issue free of
the large amount of less-directed historical context)
Fixes#17301Fixes#12235Fixes#15299Fixes#15308
## Migration Guide
* Replace `ChildBuilder` with `ChildSpawnerCommands`.
* Replace calls to `.set_parent(parent_id)` with
`.insert(Parent(parent_id))`.
* Replace calls to `.replace_children()` with `.remove::<Children>()`
followed by `.add_children()`. Note that you'll need to manually despawn
any children that are not carried over.
* Replace calls to `.despawn_recursive()` with `.despawn()`.
* Replace calls to `.despawn_descendants()` with
`.despawn_related::<Children>()`.
* If you have any calls to `.despawn()` which depend on the children
being preserved, you'll need to remove the `Children` component first.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
# Objective
Occasionally bevy users will want to store systems or observer systems
in a component or resource, but they first try to store `IntoSystem`
instead of `System`, which leads to some headaches having to deal with
the `M` marker type parameter. We should recommend they use the `X`
trait instead of the `IntoX` trait in that case, as well for returning
from a function.
## Solution
Add usage notes to the `IntoX` traits about using `X` instead.
# Objective
- https://github.com/bevyengine/bevy/issues/17111
## Solution
Set the `clippy::allow_attributes` and
`clippy::allow_attributes_without_reason` lints to `warn`, and bring
`bevy_ecs` in line with the new restrictions.
## Testing
This PR is a WIP; testing will happen after it's finished.
# Objective
- Use `Clone` on `SystemParam`, when applicable, in a generic context.
## Solution
- Add some derives
## Testing
- I ran `cargo test` once.
- I didn't even look at the output.
---------
Co-authored-by: François Mockers <mockersf@gmail.com>
- `Once` renamed to `Warn`.
- `param_warn_once()` renamed to `warn_param_missing()`.
- `never_param_warn()` renamed to `ignore_param_missing()`.
Also includes changes to the documentation of the above methods.
Fixes#17262.
## Migration Guide
- `ParamWarnPolicy::Once` has been renamed to `ParamWarnPolicy::Warn`.
- `ParamWarnPolicy::param_warn_once` has been renamed to
`ParamWarnPolicy::warn_param_missing`.
- `ParamWarnPolicy::never_param_warn` has been renamed to
`ParamWarnPolicy::ignore_param_missing`.
# Objective
With the `track_location` feature, the error message of trying to
acquire an entity that was despawned pointed to the wrong line if the
entity index has been reused.
## Showcase
```rust
use bevy_ecs::prelude::*;
fn main() {
let mut world = World::new();
let e = world.spawn_empty().id();
world.despawn(e);
world.flush();
let _ = world.spawn_empty();
world.entity(e);
}
```
Old message:
```
Entity 0v1 was despawned by src/main.rs:8:19
```
New message:
```
Entity 0v1 does not exist (its index has been reused)
```
# Objective
Stumbled upon a `from <-> form` transposition while reviewing a PR,
thought it was interesting, and went down a bit of a rabbit hole.
## Solution
Fix em
# Objective
Rework / build on #17043 to simplify the implementation. #17043 should
be merged first, and the diff from this PR will get much nicer after it
is merged (this PR is net negative LOC).
## Solution
1. Command and EntityCommand have been vastly simplified. No more marker
components. Just one function.
2. Command and EntityCommand are now generic on the return type. This
enables result-less commands to exist, and allows us to statically
distinguish between fallible and infallible commands, which allows us to
skip the "error handling overhead" for cases that don't need it.
3. There are now only two command queue variants: `queue` and
`queue_fallible`. `queue` accepts commands with no return type.
`queue_fallible` accepts commands that return a Result (specifically,
one that returns an error that can convert to
`bevy_ecs::result::Error`).
4. I've added the concept of the "default error handler", which is used
by `queue_fallible`. This is a simple direct call to the `panic()` error
handler by default. Users that want to override this can enable the
`configurable_error_handler` cargo feature, then initialize the
GLOBAL_ERROR_HANDLER value on startup. This is behind a flag because
there might be minor overhead with `OnceLock` and I'm guessing this will
be a niche feature. We can also do perf testing with OnceLock if someone
really wants it to be used unconditionally, but I don't personally feel
the need to do that.
5. I removed the "temporary error handler" on Commands (and all code
associated with it). It added more branching, made Commands bigger /
more expensive to initialize (note that we construct it at high
frequencies / treat it like a pointer type), made the code harder to
follow, and introduced a bunch of additional functions. We instead rely
on the new default error handler used in `queue_fallible` for most
things. In the event that a custom handler is required,
`handle_error_with` can be used.
6. EntityCommand now _only_ supports functions that take
`EntityWorldMut` (and all existing entity commands have been ported).
Removing the marker component from EntityCommand hinged on this change,
but I strongly believe this is for the best anyway, as this sets the
stage for more efficient batched entity commands.
7. I added `EntityWorldMut::resource` and the other variants for more
ergonomic resource access on `EntityWorldMut` (removes the need for
entity.world_scope, which also incurs entity-lookup overhead).
## Open Questions
1. I believe we could merge `queue` and `queue_fallible` into a single
`queue` which accepts both fallible and infallible commands (via the
introduction of a `QueueCommand` trait). Is this desirable?
# Objective
Many instances of `clippy::too_many_arguments` linting happen to be on
systems - functions which we don't call manually, and thus there's not
much reason to worry about the argument count.
## Solution
Allow `clippy::too_many_arguments` globally, and remove all lint
attributes related to it.
## Objective
Fixes#2004Fixes#3845Fixes#7118Fixes#10166
## Solution
- The crux of this PR is the new `Command::with_error_handling` method.
This wraps the relevant command in another command that, when applied,
will apply the original command and handle any resulting errors.
- To enable this, `Command::apply` and `EntityCommand::apply` now return
`Result`.
- `Command::with_error_handling` takes as a parameter an error handler
of the form `fn(&mut World, CommandError)`, which it passes the error
to.
- `CommandError` is an enum that can be either `NoSuchEntity(Entity)` or
`CommandFailed(Box<dyn Error>)`.
### Closures
- Closure commands can now optionally return `Result`, which will be
passed to `with_error_handling`.
### Commands
- Fallible commands can be queued with `Commands::queue_fallible` and
`Commands::queue_fallible_with`, which call `with_error_handling` before
queuing them (using `Commands::queue` will queue them without error
handling).
- `Commands::queue_fallible_with` takes an `error_handler` parameter,
which will be used by `with_error_handling` instead of a command's
default.
- The `command` submodule provides unqueued forms of built-in fallible
commands so that you can use them with `queue_fallible_with`.
- There is also an `error_handler` submodule that provides simple error
handlers for convenience.
### Entity Commands
- `EntityCommand` now automatically checks if the entity exists before
executing the command, and returns `NoSuchEntity` if it doesn't.
- Since all entity commands might need to return an error, they are
always queued with error handling.
- `EntityCommands::queue_with` takes an `error_handler` parameter, which
will be used by `with_error_handling` instead of a command's default.
- The `entity_command` submodule provides unqueued forms of built-in
entity commands so that you can use them with `queue_with`.
### Defaults
- In the future, commands should all fail according to the global error
handling setting. That doesn't exist yet though.
- For this PR, commands all fail the way they do on `main`.
- Both now and in the future, the defaults can be overridden by
`Commands::override_error_handler` (or equivalent methods on
`EntityCommands` and `EntityEntryCommands`).
- `override_error_handler` takes an error handler (`fn(&mut World,
CommandError)`) and passes it to every subsequent command queued with
`Commands::queue_fallible` or `EntityCommands::queue`.
- The `_with` variants of the queue methods will still provide an error
handler directly to the command.
- An override can be reset with `reset_error_handler`.
## Future Work
- After a universal error handling mode is added, we can change all
commands to fail that way by default.
- Once we have all commands failing the same way (which would require
either the full removal of `try` variants or just making them useless
while they're deprecated), `queue_fallible_with_default` could be
removed, since its only purpose is to enable commands having different
defaults.
# Background
In `no_std` compatible crates, there is often an `std` feature which
will allow access to the standard library. Currently, with the `std`
feature _enabled_, the
[`std::prelude`](https://doc.rust-lang.org/std/prelude/index.html) is
implicitly imported in all modules. With the feature _disabled_, instead
the [`core::prelude`](https://doc.rust-lang.org/core/prelude/index.html)
is implicitly imported. This creates a subtle and pervasive issue where
`alloc` items _may_ be implicitly included (if `std` is enabled), or
must be explicitly included (if `std` is not enabled).
# Objective
- Make the implicit imports for `no_std` crates consistent regardless of
what features are/not enabled.
## Solution
- Replace the `cfg_attr` "double negative" `no_std` attribute with
conditional compilation to _include_ `std` as an external crate.
```rust
// Before
#![cfg_attr(not(feature = "std"), no_std)]
// After
#![no_std]
#[cfg(feature = "std")]
extern crate std;
```
- Fix imports that are currently broken but are only now visible with
the above fix.
## Testing
- CI
## Notes
I had previously used the "double negative" version of `no_std` based on
general consensus that it was "cleaner" within the Rust embedded
community. However, this implicit prelude issue likely was considered
when forming this consensus. I believe the reason why is the items most
affected by this issue are provided by the `alloc` crate, which is
rarely used within embedded but extensively used within Bevy.
# Objective
- As stated in the related issue, this PR is to better align the feature
flag name with what it actually does and the plans for the future.
- Fixes#16852
## Solution
- Simple find / replace
## Testing
- Local run of `cargo run -p ci`
## Migration Guide
The `track_change_detection` feature flag has been renamed to
`track_location` to better reflect its extended capabilities.
# Objective
- #16589 added an enum to switch between fallible and infallible system.
This branching should be unnecessary if we wrap infallible systems in a
function to return `Ok(())`.
## Solution
- Create a wrapper system for `System<(), ()>`s that returns `Ok` on the
call to `run` and `run_unsafe`. The wrapper should compile out, but I
haven't checked.
- I removed the `impl IntoSystemConfigs for BoxedSystem<(), ()>` as I
couldn't figure out a way to keep the impl without double boxing.
## Testing
- ran `many_foxes` example to check if it still runs.
## Migration Guide
- `IntoSystemConfigs` has been removed for `BoxedSystem<(), ()>`. Either
use `InfallibleSystemWrapper` before boxing or make your system return
`bevy::ecs::prelude::Result`.
# Objective
- Made certain methods public for advanced use cases. Methods that
returns mutable references are marked as unsafe due to the possibility
of violating internal lifetime constraint assumptions.
- Fixes an issue introduced by #15184
## Objective
Commands were previously limited to structs that implemented `Command`.
Now there are blanket implementations for closures, which (in my
opinion) are generally preferable.
Internal commands within `commands/mod.rs` have been switched from
structs to closures, but there are a number of internal commands in
other areas of the engine that still use structs. I'd like to tidy these
up by moving their implementations to methods on
`World`/`EntityWorldMut` and changing `Commands` to use those methods
through closures.
This PR handles the following:
- `TriggerEvent` and `EmitDynamicTrigger` double as commands and helper
structs, and can just be moved to `World` methods.
- Four structs that enabled insertion/removal of components via
reflection. This functionality shouldn't be exclusive to commands, and
can be added to `EntityWorldMut`.
- Five structs that mostly just wrapped `World` methods, and can be
replaced with closures that do the same thing.
## Solution
- __Observer Triggers__ (`observer/trigger_event.rs` and
`observer/mod.rs`)
- Moved the internals of `TriggerEvent` to the `World` methods that used
it.
- Replaced `EmitDynamicTrigger` with two `World` methods:
- `trigger_targets_dynamic`
- `trigger_targets_dynamic_ref`
- `TriggerTargets` was now the only thing in
`observer/trigger_event.rs`, so it's been moved to `observer/mod.rs` and
`trigger_event.rs` was deleted.
- __Reflection Insert/Remove__ (`reflect/entity_commands.rs`)
- Replaced the following `Command` impls with equivalent methods on
`EntityWorldMut`:
- `InsertReflect` -> `insert_reflect`
- `InsertReflectWithRegistry` -> `insert_reflect_with_registry`
- `RemoveReflect` -> `remove_reflect`
- `RemoveReflectWithRegistry` -> `remove_reflect_with_registry`
- __System Registration__ (`system/system_registry.rs`)
- The following `Command` impls just wrapped a `World` method and have
been replaced with closures:
- `RunSystemWith`
- `UnregisterSystem`
- `RunSystemCachedWith`
- `UnregisterSystemCached`
- `RegisterSystem` called a helper function that basically worked as a
constructor for `RegisteredSystem` and made sure it came with a marker
component. That helper function has been replaced with
`RegisteredSystem::new` and a `#[require]`.
## Possible Addition
The extension trait that adds the reflection commands,
`ReflectCommandExt`, isn't strictly necessary; we could just `impl
EntityCommands`. We could even move them to the same files as the main
impls and put it behind a `#[cfg]`.
The PR that added it [had a similar
conversation](https://github.com/bevyengine/bevy/pull/8895#discussion_r1234713671)
and decided to stick with the trait, but we could revisit it here if so
desired.
# Objective
Fixes#16104
## Solution
I removed all instances of `:?` and put them back one by one where it
caused an error.
I removed some bevy_utils helper functions that were only used in 2
places and don't add value. See: #11478
## Testing
CI should catch the mistakes
## Migration Guide
`bevy::utils::{dbg,info,warn,error}` were removed. Use
`bevy::utils::tracing::{debug,info,warn,error}` instead.
---------
Co-authored-by: SpecificProtagonist <vincentjunge@posteo.net>
# Objective
- First step for #16718
- #16589 introduced an api that can only ignore errors, which is risky
## Solution
- Panic instead of just ignoring the errors
## Testing
- Changed the `fallible_systems` example to return an error
```
Encountered an error in system `fallible_systems::setup`: TooManyVertices { subdivisions: 300, number_of_resulting_points: 906012 }
Encountered a panic in system `fallible_systems::setup`!
Encountered a panic in system `bevy_app::main_schedule::Main::run_main`!
```
## Objective
I believe these started as structs, back when that was how commands had
to be implemented. Now they just hide implementation details.
## Solution
Remove the helper functions and move each implementation into its
respective method, except for the ones that actually reduce code
duplication.
# Objective
Fixes: #16578
## Solution
This is a patch fix, proper fix requires a breaking change.
Added `Panic` enum variant and using is as the system meta default.
Warn once behavior can be enabled same way disabling panic (originally
disabling wans) is.
To fix an issue with the current architecture, where **all** combinator
system params get checked together,
combinator systems only check params of the first system.
This will result in old, panicking behavior on subsequent systems and
will be fixed in 0.16.
## Testing
Ran unit tests and `fallible_params` example.
---------
Co-authored-by: François Mockers <mockersf@gmail.com>
Co-authored-by: François Mockers <francois.mockers@vleue.com>
# Objective
Simplify the code by using `macro_rules` instead of a proc macro where
possible.
## Solution
Replace `impl_param_set` proc macro with a `macro_rules` macro.
# Objective
In current Bevy, it is very inconvenient to mutably retrieve a
user-provided list of entities more than one element at a time.
If the list contains any duplicate entities, we risk mutable aliasing.
Users of `Query::iter_many_mut` do not have access to `Iterator` trait,
and thus miss out on common functionality, for instance collecting their
`QueryManyIter`.
We can circumvent this issue with validation, however that entails
checking every entity against all others for inequality, or utilizing an
`EntityHashSet`. Even if an entity list remains unchanged, this
validation is/would have to be redone every time we wish to fetch with
the list.
This presents a lot of wasted work, as we often trivially know an entity
list to be unique f.e.: `QueryIter` will fetch every `Entity` once and
only once.
As more things become entities – assets, components, queries – this
issue will become more pronounced.
`get_many`/`many`/`iter_many`/`par_iter_many`-like functionality is all
affected.
## Solution
The solution this PR proposes is to introduce functionality built around
a new trait: `EntitySet`.
The goal is to preserve the property of "uniqueness" in a list wherever
possible, and then rely on it as a bound within new `*_many_unique`
methods to avoid the need for validation.
This is achieved using `Iterator`:
`EntitySet` is blanket implemented for any `T` that implements
`IntoIterator<IntoIter: EntitySetIterator>`.
`EntitySetIterator` is the unsafe trait that actually guarantees an
iterator to be "unique" via its safety contract.
We define an "Iterator over unique entities" as: "No two entities
returned by the iterator may compare equal."
For iterators that cannot return more than 1 element, this is trivially
true.
Whether an iterator can satisfy this is up to the `EntitySetIterator`
implementor to ensure, hence the unsafe.
However, this is not yet a complete solution. Looking at the signature
of `iter_many`, we find that `IntoIterator::Item` is not `Entity`, but
is instead bounded by the `Borrow<Entity>` trait. That is because
iteration without consuming the collection will often yield us
references, not owned items.
`Borrow<Entity>` presents an issue: The `Borrow` docs state that `x = y`
should equal `x.borrow() = y.borrow()`, but unsafe cannot rely on this
for soundness. We run into similar problems with other trait
implementations of any `Borrow<Entity>` type: `PartialEq`, `Eq`,
`PartialOrd`, `Ord`, `Hash`, `Clone`, `Borrow`, and `BorrowMut`.
This PR solves this with the unsafe `TrustedEntityBorrow` trait:
Any implementor promises that the behavior of the aforementioned traits
matches that of the underlying entity.
While `Borrow<Entity>` was the inspiration, we use our own counterpart
trait `EntityBorrow` as the supertrait to `TrustedEntityBorrow`, so we
can circumvent the limitations of the existing `Borrow<T>` blanket
impls.
All together, these traits allow us to implement `*_many_unique`
functionality with a lone `EntitySet` bound.
`EntitySetIterator` is implemented for all the std iterators and
iterator adapters that guarantee or preserve uniqueness, so we can
filter, skip, take, step, reverse, ... our unique entity iterators
without worry!
Sadly, current `HashSet` iterators do not carry the necessary type
information with them to determine whether the source `HashSet` produces
logic errors; A malicious `Hasher` could compromise a `HashSet`.
`HashSet` iteration is generally discouraged in the first place, so we
also exclude the set operation iterators, even though they do carry the
`Hasher` type parameter.
`BTreeSet` implements `EntitySet` without any problems.
If an iterator type cannot guarantee uniqueness at compile time, then a
user can still attach `EntitySetIterator` to an individual instance of
that type via `UniqueEntityIter::from_iterator_unchecked`.
With this, custom types can use `UniqueEntityIter<I>` as their
`IntoIterator::IntoIter` type, if necessary.
This PR is focused on the base concept, and expansions on it are left
for follow-up PRs. See "Potential Future Work" below.
## Testing
Doctests on `iter_many_unique`/`iter_many_unique_mut` + 2 tests in
entity_set.rs.
## Showcase
```rust
// Before:
fn system(player_list: Res<SomeUniquePlayerList>, players: Query<&mut Player>) {
let value = 0;
while let Some(player) = players.iter_many_mut(player_list).fetch_next() {
value += mem::take(player.value_mut())
}
}
// After:
fn system(player_list: Res<SomeUniquePlayerList>, players: Query<&mut Player>) {
let value = players
.iter_many_unique_mut(player_list)
.map(|player| mem::take(player.value_mut()))
.sum();
}
```
## Changelog
- added `EntityBorrow`, `TrustedEntityBorrow`, `EntitySet` and
`EntitySetIterator` traits
- added `iter_many_unique`, `iter_many_unique_mut`,
`iter_many_unique_unsafe` methods on `Query`
- added `iter_many_unique`, `iter_many_unique_mut`,
`iter_many_unique_manual` and `iter_many_unique_unchecked_manual`
methods on `QueryState`
- added corresponding `QueryManyUniqueIter`
- added `UniqueEntityIter`
## Migration Guide
Any custom type used as a `Borrow<Entity>` entity list item for an
`iter_many` method now has to implement `EntityBorrow` instead. Any type
that implements `Borrow<Entity>` can trivially implement `EntityBorrow`.
## Potential Future Work
- `ToEntitySet` trait for converting any entity iterator into an
`EntitySetIterator`
- `EntityIndexSet/Map` to tie in hashing with `EntitySet`
- add `EntityIndexSetSlice/MapSlice`
- requires: `EntityIndexSet/Map`
- Implementing `par_iter_many_unique_mut` for parallel mutable iteration
- requires: `par_iter_many`
- allow collecting into `UniqueEntityVec` to store entity sets
- add `UniqueEntitySlice`s
- Doesn't require, but should be done after: `UniqueEntityVec`
- add `UniqueEntityArray`s
- Doesn't require, but should be done after: `UniqueEntitySlice`
- `get_many_unique`/`many_unique` methods
- requires: `UniqueEntityArray`
- `World::entity_unique` to match `World::entity` methods
- Doesn't require, but makes sense after:
`get_many_unique`/`many_unique`
- implement `TrustedEntityBorrow` for the `EntityRef` family
- Doesn't require, but makes sense after: `UniqueEntityVec`
# Objective
- Contributes to #15460
## Solution
- Added the following features:
- `std` (default)
- `async_executor` (default)
- `edge_executor`
- `critical-section`
- `portable-atomic`
- Gated `tracing` in `bevy_utils` to allow compilation on certain
platforms
- Switched from `tracing` to `log` for simple message logging within
`bevy_ecs`. Note that `tracing` supports capturing from `log` so this
should be an uncontroversial change.
- Fixed imports and added feature gates as required
- Made `bevy_tasks` optional within `bevy_ecs`. Turns out it's only
needed for parallel operations which are already gated behind
`multi_threaded` anyway.
## Testing
- Added to `compile-check-no-std` CI command
- `cargo check -p bevy_ecs --no-default-features --features
edge_executor,critical-section,portable-atomic --target
thumbv6m-none-eabi`
- `cargo check -p bevy_ecs --no-default-features --features
edge_executor,critical-section`
- `cargo check -p bevy_ecs --no-default-features`
## Draft Release Notes
Bevy's core ECS now supports `no_std` platforms.
In prior versions of Bevy, it was not possible to work with embedded or
niche platforms due to our reliance on the standard library, `std`. This
has blocked a number of novel use-cases for Bevy, such as an embedded
database for IoT devices, or for creating games on retro consoles.
With this release, `bevy_ecs` no longer requires `std`. To use Bevy on a
`no_std` platform, you must disable default features and enable the new
`edge_executor` and `critical-section` features. You may also need to
enable `portable-atomic` and `critical-section` if your platform does
not natively support all atomic types and operations used by Bevy.
```toml
[dependencies]
bevy_ecs = { version = "0.16", default-features = false, features = [
# Required for platforms with incomplete atomics (e.g., Raspberry Pi Pico)
"portable-atomic",
"critical-section",
# Optional
"bevy_reflect",
"serialize",
"bevy_debug_stepping",
"edge_executor"
] }
```
Currently, this has been tested on bare-metal x86 and the Raspberry Pi
Pico. If you have trouble using `bevy_ecs` on a particular platform,
please reach out either through a GitHub issue or in the `no_std`
working group on the Bevy Discord server.
Keep an eye out for future `no_std` updates as we continue to improve
the parity between `std` and `no_std`. We look forward to seeing what
kinds of applications are now possible with Bevy!
## Notes
- Creating PR in draft to ensure CI is passing before requesting
reviews.
- This implementation has no support for multithreading in `no_std`,
especially due to `NonSend` being unsound if allowed in multithreading.
The reason is we cannot check the `ThreadId` in `no_std`, so we have no
mechanism to at-runtime determine if access is sound.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: Vic <59878206+Victoronz@users.noreply.github.com>
# Objective
Example error message beforehand:
```
error[B0001]: Query<&mut Data, ()> in system bevytest::main::{{closure}} accesses component(s)Data in a way that conflicts with a previous…
```
# Objective
Expand `track_change_detection` feature to also track entity spawns and
despawns. Use this to create better error messages.
# Solution
Adds `Entities::entity_get_spawned_or_despawned_by` as well as `{all
entity reference types}::spawned_by`.
This also removes the deprecated `get_many_entities_mut` & co (and
therefore can't land in 0.15) because we don't yet have no Polonius.
## Testing
Added a test that checks that the locations get updated and these
updates are ordered correctly vs hooks & observers.
---
## Showcase
Access location:
```rust
let mut world = World::new();
let entity = world.spawn_empty().id();
println!("spawned by: {}", world.entity(entity).spawned_by());
```
```
spawned by: src/main.rs:5:24
```
Error message (with `track_change_detection`):
```rust
world.despawn(entity);
world.entity(entity);
```
```
thread 'main' panicked at src/main.rs:11:11:
Entity 0v1#4294967296 was despawned by src/main.rs:10:11
```
and without:
```
thread 'main' panicked at src/main.rs:11:11:
Entity 0v1#4294967296 does not exist (enable `track_change_detection` feature for more details)
```
Similar error messages now also exists for `Query::get`,
`World::entity_mut`, `EntityCommands` creation and everything that
causes `B0003`, e.g.
```
error[B0003]: Could not insert a bundle (of type `MaterialMeshBundle<StandardMaterial>`) for entity Entity { index: 7, generation: 1 }, which was despawned by src/main.rs:10:11. See: https://bevyengine.org/learn/errors/#b0003
```
---------
Co-authored-by: kurk070ff <108901106+kurk070ff@users.noreply.github.com>
Co-authored-by: Freya Pines <freya@MacBookAir.lan>
Co-authored-by: Freya Pines <freya@Freyas-MacBook-Air.local>
Co-authored-by: Matty Weatherley <weatherleymatthew@gmail.com>
