Early implementation. I still have to fix the documentation and consider
writing a small migration guide.
Questions left to answer:
* [x] should thickness be an overridable constant?
* [x] is there a better way to implement `Eq`/`Hash` for `SSAOMethod`?
* [x] do we want to keep the linear sampler for the depth texture?
* [x] is there a better way to separate the logic than preprocessor
macros?
![vbao](https://github.com/bevyengine/bevy/assets/4136413/2a8a0389-2add-4c2e-be37-e208e52dcd25)
## Migration guide
SSAO algorithm was changed from GTAO to VBAO (visibility bitmasks). A
new field, `constant_object_thickness`, was added to
`ScreenSpaceAmbientOcclusion`. `ScreenSpaceAmbientOcclusion` also lost
its `Eq` and `Hash` implementations.
---------
Co-authored-by: JMS55 <47158642+JMS55@users.noreply.github.com>
# Objective
Relevant: #15208
## Solution
I went ahead and added the variadics documentation in all applicable
locations.
## Testing
- I built the documentation and inspected it to see whether the feature
is there.
As discussed in #15521
- Partial revert of #14897, reverting the change to the methods to
consume `self`
- The `insert_if` method is kept
The migration guide of #14897 should be removed
Closes#15521
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
# Objective
- Remove dependency in bevy_asset to bevy_winit
- First step for #15565
## Solution
- the static `ANDROID_APP` and the `android_activity` reexport are now
in `bevy_window`
## Migration Guide
If you use the `android_activity` reexport from
`bevy::winit::android_activity`, it is now in
`bevy:🪟:android_activity`. Same for the `ANDROID_APP` static
## Objective
I am using BRP for a web inspector. To get components from a entity is
first do a `bevy/list` on the specific entity and then use the result in
a `bevy/get` request. The problem with this is `bevy/list` returns all
components even if they aren't reflect-able (which is what I expect) but
when I then do a `bevy/get` request even if all bar one of the
components are reflect-able the request will fail.
## Solution
Update the `bevy/get` response to include a map of components like it
did for successful request and a map of errors. This means if one or
more components are not present on the entity or cannot be reflected it
will not fail the entire request.
I also only did `bevy/get` as I don't think any of the other methods
would benefit from this.
## Testing
I tested this with my inspector and with a http client and it worked as
expected.
---------
Co-authored-by: Pablo Reinhardt <126117294+pablo-lua@users.noreply.github.com>
# Objective
### The Problem
Currently, the reflection deserializers give little control to users for
how a type is deserialized. The most control a user can have is to
register `ReflectDeserialize`, which will use a type's `Deserialize`
implementation.
However, there are times when a type may require slightly more control.
For example, let's say we want to make Bevy's `Mesh` easier to
deserialize via reflection (assume `Mesh` actually implemented
`Reflect`). Since we want this to be extensible, we'll make it so users
can use their own types so long as they satisfy `Into<Mesh>`. The end
result should allow users to define a RON file like:
```rust
{
"my_game::meshes::Sphere": (
radius: 2.5
)
}
```
### The Current Solution
Since we don't know the types ahead of time, we'll need to use
reflection. Luckily, we can access type information dynamically via the
type registry. Let's make a custom type data struct that users can
register on their types:
```rust
pub struct ReflectIntoMesh {
// ...
}
impl<T: FromReflect + Into<Mesh>> FromType<T> for ReflectIntoMesh {
fn from_type() -> Self {
// ...
}
}
```
Now we'll need a way to use this type data during deserialization.
Unfortunately, we can't use `Deserialize` since we need access to the
registry. This is where `DeserializeSeed` comes in handy:
```rust
pub struct MeshDeserializer<'a> {
pub registry: &'a TypeRegistry
}
impl<'a, 'de> DeserializeSeed<'de> for MeshDeserializer<'a> {
type Value = Mesh;
fn deserialize<D>(self, deserializer: D) -> Result<Self::Value, D::Error>
where
D: serde::Deserializer<'de>,
{
struct MeshVisitor<'a> {
registry: &'a TypeRegistry
}
impl<'a, 'de> Visitor<'de> for MeshVisitor<'a> {
fn expecting(&self, formatter: &mut Formatter) -> std::fmt::Result {
write!(formatter, "map containing mesh information")
}
fn visit_map<A>(self, mut map: A) -> Result<Self::Value, serde:🇩🇪:Error> where A: MapAccess<'de> {
// Parse the type name
let type_name = map.next_key::<String>()?.unwrap();
// Deserialize the value based on the type name
let registration = self.registry
.get_with_name(&type_name)
.expect("should be registered");
let value = map.next_value_seed(TypedReflectDeserializer {
registration,
registry: self.registry,
})?;
// Convert the deserialized value into a `Mesh`
let into_mesh = registration.data::<ReflectIntoMesh>().unwrap();
Ok(into_mesh.into(value))
}
}
}
}
```
### The Problem with the Current Solution
The solution above works great when all we need to do is deserialize
`Mesh` directly. But now, we want to be able to deserialize a struct
like this:
```rust
struct Fireball {
damage: f32,
mesh: Mesh,
}
```
This might look simple enough and should theoretically be no problem for
the reflection deserializer to handle, but this is where our
`MeshDeserializer` solution starts to break down.
In order to use `MeshDeserializer`, we need to have access to the
registry. The reflection deserializers have access to that, but we have
no way of borrowing it for our own deserialization since they have no
way of knowing about `MeshDeserializer`.
This means we need to implement _another_ `DeserializeSeed`— this time
for `Fireball`!
And if we decided to put `Fireball` inside another type, well now we
need one for that type as well.
As you can see, this solution does not scale well and results in a lot
of unnecessary boilerplate for the user.
## Solution
> [!note]
> This PR originally only included the addition of
`DeserializeWithRegistry`. Since then, a corresponding
`SerializeWithRegistry` trait has also been added. The reasoning and
usage is pretty much the same as the former so I didn't bother to update
the full PR description.
Created the `DeserializeWithRegistry` trait and
`ReflectDeserializeWithRegistry` type data.
The `DeserializeWithRegistry` trait works like a standard `Deserialize`
but provides access to the registry. And by registering the
`ReflectDeserializeWithRegistry` type data, the reflection deserializers
will automatically use the `DeserializeWithRegistry` implementation,
just like it does for `Deserialize`.
All we need to do is make the following changes:
```diff
#[derive(Reflect)]
+ #[reflect(DeserializeWithRegistry)]
struct Mesh {
// ...
}
- impl<'a, 'de> DeserializeSeed<'de> for MeshDeserializer<'a> {
- type Value = Mesh;
- fn deserialize<D>(self, deserializer: D) -> Result<Self::Value, D::Error>
+ impl<'de> DeserializeWithRegistry<'de> for Mesh {
+ fn deserialize<D>(deserializer: D, registry: &TypeRegistry) -> Result<Self, D::Error>
where
D: serde::Deserializer<'de>,
{
// ...
}
}
```
Now, any time the reflection deserializer comes across `Mesh`, it will
opt to use its `DeserializeWithRegistry` implementation. And this means
we no longer need to create a whole slew of `DeserializeSeed` types just
to deserialize `Mesh`.
### Why not a trait like `DeserializeSeed`?
While this would allow for anyone to define a deserializer for `Mesh`,
the problem is that it means __anyone can define a deserializer for
`Mesh`.__ This has the unfortunate consequence that users can never be
certain that their registration of `ReflectDeserializeSeed` is the one
that will actually be used.
We could consider adding something like that in the future, but I think
this PR's solution is much safer and follows the example set by
`ReflectDeserialize`.
### What if we made the `TypeRegistry` globally available?
This is one potential solution and has been discussed before (#6101).
However, that change is much more controversial and comes with its own
set of disadvantages (can't have multiple registries such as with
multiple worlds, likely some added performance cost with each access,
etc.).
### Followup Work
Once this PR is merged, we should consider merging `ReflectDeserialize`
into `DeserializeWithRegistry`. ~~There is already a blanket
implementation to make this transition generally pretty
straightforward.~~ The blanket implementations were removed for the sake
of this PR and will need to be re-added in the followup. I would propose
that we first mark `ReflectDeserialize` as deprecated, though, before we
outright remove it in a future release.
---
## Changelog
- Added the `DeserializeReflect` trait and `ReflectDeserializeReflect`
type data
- Added the `SerializeReflect` trait and `ReflectSerializeReflect` type
data
- Added `TypedReflectDeserializer::of` convenience constructor
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: aecsocket <43144841+aecsocket@users.noreply.github.com>
# Objective
- Fixes#14826
- For context, see #15238
## Solution
Add a `GhostNode` component to `bevy_ui` and update all the relevant
systems to use it to traverse for UI children.
- [x] `ghost_hierarchy` module
- [x] Add `GhostNode`
- [x] Add `UiRootNodes` system param for iterating (ghost-aware) UI root
nodes
- [x] Add `UiChildren` system param for iterating (ghost-aware) UI
children
- [x] Update `layout::ui_layout_system`
- [x] Use ghost-aware root nodes for camera updates
- [x] Update and remove children in taffy
- [x] Initial spawn
- [x] Detect changes on nested UI children
- [x] Use ghost-aware children traversal in
`update_uinode_geometry_recursive`
- [x] Update the rest of the UI systems to use the ghost hierarchy
- [x] `stack::ui_stack_system`
- [x] `update::`
- [x] `update_clipping_system`
- [x] `update_target_camera_system`
- [x] `accessibility::calc_name`
## Testing
- [x] Added a new example `ghost_nodes` that can be used as a testbed.
- [x] Added unit tests for _some_ of the traversal utilities in
`ghost_hierarchy`
- [x] Ensure this fulfills the needs for currently known use cases
- [x] Reactivity libraries (test with `bevy_reactor`)
- [ ] Text spans (mentioned by koe [on
discord](https://discord.com/channels/691052431525675048/1285371432460881991/1285377442998915246))
---
## Performance
[See comment
below](https://github.com/bevyengine/bevy/pull/15341#issuecomment-2385456820)
## Migration guide
Any code that previously relied on `Parent`/`Children` to iterate UI
children may now want to use `bevy_ui::UiChildren` to ensure ghost nodes
are skipped, and their first descendant Nodes included.
UI root nodes may now be children of ghost nodes, which means
`Without<Parent>` might not query all root nodes. Use
`bevy_ui::UiRootNodes` where needed to iterate root nodes instead.
## Potential future work
- Benchmarking/optimizations of hierarchies containing lots of ghost
nodes
- Further exploration of UI hierarchies and markers for root nodes/leaf
nodes to create better ergonomics for things like `UiLayer` (world-space
ui)
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: UkoeHB <37489173+UkoeHB@users.noreply.github.com>
# Objective
- Prepare `TextPipeline` to work with multi-entity text blocks. See
https://github.com/bevyengine/bevy/discussions/15014
## Solution
- Refactor `TextPipeline::update_buffer` to accept an iterator instead
of slice. Adjust `update_buffer` implementation to only iterate spans
once instead of three times (which would require iterating a hierarchy
three times with multi-entity blocks).
## Testing
- Tested with `text_debug` example.
# Objective
Again, a step forward in the migration to required components: a bunch
of camera rendering cormponents!
Note that this does not include the camera components themselves yet,
because the naming and API for `Camera` hasn't been fully decided yet.
## Solution
As per the [selected
proposals](https://hackmd.io/@bevy/required_components/%2FpiqD9GOdSFKZZGzzh3C7Uw):
- Deprecate `MotionBlurBundle` in favor of the `MotionBlur` component
- Deprecate `TemporalAntiAliasBundle` in favor of the
`TemporalAntiAliasing` component
- Deprecate `ScreenSpaceAmbientOcclusionBundle` in favor of the
`ScreenSpaceAmbientOcclusion` component
- Deprecate `ScreenSpaceReflectionsBundle` in favor of the
`ScreenSpaceReflections` component
---
## Migration Guide
`MotionBlurBundle`, `TemporalAntiAliasBundle`,
`ScreenSpaceAmbientOcclusionBundle`, and `ScreenSpaceReflectionsBundle`
have been deprecated in favor of the `MotionBlur`,
`TemporalAntiAliasing`, `ScreenSpaceAmbientOcclusion`, and
`ScreenSpaceReflections` components instead. Inserting them will now
also insert the other components required by them automatically.
# Objective
What's that? Another PR for the grand migration to required components?
This time, audio!
## Solution
Deprecate `AudioSourceBundle`, `AudioBundle`, and `PitchBundle`, as per
the [chosen
proposal](https://hackmd.io/@bevy/required_components/%2Fzxgp-zMMRUCdT7LY1ZDQwQ).
However, we cannot call the component `AudioSource`, because that's what
the stored asset is called. I deliberated on a few names, like
`AudioHandle`, or even just `Audio`, but landed on `AudioPlayer`, since
it's probably the most accurate and "nice" name for this. Open to
alternatives though.
---
## Migration Guide
Replace all insertions of `AudioSoucreBundle`, `AudioBundle`, and
`PitchBundle` with the `AudioPlayer` component. The other components
required by it will now be inserted automatically.
In cases where the generics cannot be inferred, you may need to specify
them explicitly. For example:
```rust
commands.spawn(AudioPlayer::<AudioSource>(asset_server.load("sounds/sick_beats.ogg")));
```
# Objective
A step in the migration to required components: scenes!
## Solution
As per the [selected
proposal](https://hackmd.io/@bevy/required_components/%2FPJtNGVMMQhyM0zIvCJSkbA):
- Deprecate `SceneBundle` and `DynamicSceneBundle`.
- Add `SceneRoot` and `DynamicSceneRoot` components, which wrap a
`Handle<Scene>` and `Handle<DynamicScene>` respectively.
## Migration Guide
Asset handles for scenes and dynamic scenes must now be wrapped in the
`SceneRoot` and `DynamicSceneRoot` components. Raw handles as components
no longer spawn scenes.
Additionally, `SceneBundle` and `DynamicSceneBundle` have been
deprecated. Instead, use the scene components directly.
Previously:
```rust
let model_scene = asset_server.load(GltfAssetLabel::Scene(0).from_asset("model.gltf"));
commands.spawn(SceneBundle {
scene: model_scene,
transform: Transform::from_xyz(-4.0, 0.0, -3.0),
..default()
});
```
Now:
```rust
let model_scene = asset_server.load(GltfAssetLabel::Scene(0).from_asset("model.gltf"));
commands.spawn((
SceneRoot(model_scene),
Transform::from_xyz(-4.0, 0.0, -3.0),
));
```
# Objective
- Improve code quality in preparation for
https://github.com/bevyengine/bevy/discussions/15014
## Solution
- Rename BreakLineOn to LineBreak.
## Migration Guide
`BreakLineOn` was renamed to `LineBreak`, and paramters named
`linebreak_behavior` were renamed to `linebreak`.
# Objective
Add two features to switch bevy to use `NativeActivity` or
`GameActivity` on Android, use `GameActivity` by default.
Also close #12058 and probably #12026 .
## Solution
Add two features to the corresponding crates so you can toggle it, like
what `winit` and `android-activity` crate did.
---
## Changelog
Removed default `NativeActivity` feature implementation for Android,
added two new features to enable `NativeActivity` and `GameActivity`,
and use `GameActivity` by default.
## Migration Guide
Because `cargo-apk` is not compatible with `GameActivity`,
building/running using `cargo apk build/run -p bevy_mobile_example` is
no longer possible.
Users should follow the new workflow described in document.
---------
Co-authored-by: François Mockers <francois.mockers@vleue.com>
Co-authored-by: BD103 <59022059+BD103@users.noreply.github.com>
Co-authored-by: Rich Churcher <rich.churcher@gmail.com>
# Objective
A big step in the migration to required components: meshes and
materials!
## Solution
As per the [selected
proposal](https://hackmd.io/@bevy/required_components/%2Fj9-PnF-2QKK0on1KQ29UWQ):
- Deprecate `MaterialMesh2dBundle`, `MaterialMeshBundle`, and
`PbrBundle`.
- Add `Mesh2d` and `Mesh3d` components, which wrap a `Handle<Mesh>`.
- Add `MeshMaterial2d<M: Material2d>` and `MeshMaterial3d<M: Material>`,
which wrap a `Handle<M>`.
- Meshes *without* a mesh material should be rendered with a default
material. The existence of a material is determined by
`HasMaterial2d`/`HasMaterial3d`, which is required by
`MeshMaterial2d`/`MeshMaterial3d`. This gets around problems with the
generics.
Previously:
```rust
commands.spawn(MaterialMesh2dBundle {
mesh: meshes.add(Circle::new(100.0)).into(),
material: materials.add(Color::srgb(7.5, 0.0, 7.5)),
transform: Transform::from_translation(Vec3::new(-200., 0., 0.)),
..default()
});
```
Now:
```rust
commands.spawn((
Mesh2d(meshes.add(Circle::new(100.0))),
MeshMaterial2d(materials.add(Color::srgb(7.5, 0.0, 7.5))),
Transform::from_translation(Vec3::new(-200., 0., 0.)),
));
```
If the mesh material is missing, previously nothing was rendered. Now,
it renders a white default `ColorMaterial` in 2D and a
`StandardMaterial` in 3D (this can be overridden). Below, only every
other entity has a material:
![Näyttökuva 2024-09-29
181746](https://github.com/user-attachments/assets/5c8be029-d2fe-4b8c-ae89-17a72ff82c9a)
![Näyttökuva 2024-09-29
181918](https://github.com/user-attachments/assets/58adbc55-5a1e-4c7d-a2c7-ed456227b909)
Why white? This is still open for discussion, but I think white makes
sense for a *default* material, while *invalid* asset handles pointing
to nothing should have something like a pink material to indicate that
something is broken (I don't handle that in this PR yet). This is kind
of a mix of Godot and Unity: Godot just renders a white material for
non-existent materials, while Unity renders nothing when no materials
exist, but renders pink for invalid materials. I can also change the
default material to pink if that is preferable though.
## Testing
I ran some 2D and 3D examples to test if anything changed visually. I
have not tested all examples or features yet however. If anyone wants to
test more extensively, it would be appreciated!
## Implementation Notes
- The relationship between `bevy_render` and `bevy_pbr` is weird here.
`bevy_render` needs `Mesh3d` for its own systems, but `bevy_pbr` has all
of the material logic, and `bevy_render` doesn't depend on it. I feel
like the two crates should be refactored in some way, but I think that's
out of scope for this PR.
- I didn't migrate meshlets to required components yet. That can
probably be done in a follow-up, as this is already a huge PR.
- It is becoming increasingly clear to me that we really, *really* want
to disallow raw asset handles as components. They caused me a *ton* of
headache here already, and it took me a long time to find every place
that queried for them or inserted them directly on entities, since there
were no compiler errors for it. If we don't remove the `Component`
derive, I expect raw asset handles to be a *huge* footgun for users as
we transition to wrapper components, especially as handles as components
have been the norm so far. I personally consider this to be a blocker
for 0.15: we need to migrate to wrapper components for asset handles
everywhere, and remove the `Component` derive. Also see
https://github.com/bevyengine/bevy/issues/14124.
---
## Migration Guide
Asset handles for meshes and mesh materials must now be wrapped in the
`Mesh2d` and `MeshMaterial2d` or `Mesh3d` and `MeshMaterial3d`
components for 2D and 3D respectively. Raw handles as components no
longer render meshes.
Additionally, `MaterialMesh2dBundle`, `MaterialMeshBundle`, and
`PbrBundle` have been deprecated. Instead, use the mesh and material
components directly.
Previously:
```rust
commands.spawn(MaterialMesh2dBundle {
mesh: meshes.add(Circle::new(100.0)).into(),
material: materials.add(Color::srgb(7.5, 0.0, 7.5)),
transform: Transform::from_translation(Vec3::new(-200., 0., 0.)),
..default()
});
```
Now:
```rust
commands.spawn((
Mesh2d(meshes.add(Circle::new(100.0))),
MeshMaterial2d(materials.add(Color::srgb(7.5, 0.0, 7.5))),
Transform::from_translation(Vec3::new(-200., 0., 0.)),
));
```
If the mesh material is missing, a white default material is now used.
Previously, nothing was rendered if the material was missing.
The `WithMesh2d` and `WithMesh3d` query filter type aliases have also
been removed. Simply use `With<Mesh2d>` or `With<Mesh3d>`.
---------
Co-authored-by: Tim Blackbird <justthecooldude@gmail.com>
Co-authored-by: Carter Anderson <mcanders1@gmail.com>
# Objective
Another part of the migration to required components: fog volumes!
## Solution
Deprecate `FogVolumeBundle` and make `FogVolume` require `Transform` and
`Visibility`, as per the [chosen
proposal](https://hackmd.io/@bevy/required_components/%2FcO7JPSAQR5G0J_j5wNwtOQ).
---
## Migration Guide
Replace all insertions of `FogVolumeBundle` with the `Visibility`
component. The other components required by it will now be inserted
automatically.
Previous PR https://github.com/bevyengine/bevy/pull/14549 was closed in
error and couldn't be reopened since I had updated the branch
😿
# Objective
Fixes#14465
## Solution
`ReflectMapEntities` now works similarly to `MapEntities` in that it
works on the reflected value itself rather than the component in the
world after insertion. This makes it so that observers see the remapped
entities on insertion rather than the entity IDs from the scene.
`ReflectMapEntities` now works for both components and resources, so we
only need the one.
## Testing
* New unit test for `Observer`s + `DynamicScene`s
* New unit test for `Observer`s + `Scene`s
* Open to suggestions for other tests!
---
## Migration Guide
- Consumers of `ReflectMapEntities` will need to call `map_entities` on
values prior to inserting them into the world.
- Implementors of `MapEntities` will need to remove the `mappings`
method, which is no longer needed for `ReflectMapEntities` and has been
removed from the trait.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: Hennadii Chernyshchyk <genaloner@gmail.com>
# Objective
- First step towards #15558
## Solution
- Rename `get_vertex_buffer_data` to `create_packed_vertex_buffer_data`
to make it clear that it is not "free" and actually allocates
- Compute length analytically for preallocation instead of creating the
buffer to get its length and immediately discard it
- Use existing vertex attribute size calculation method to reduce code
duplication
- Fix a bug where mesh index data was being replaced by unnecessarily
newly created mesh vertex data in some cases
- Overall reduces mesh copies by two. We still have plenty to go, but
these were the easy ones.
## Testing
- I ran 3d_scene, lighting, and many_cubes, they look fine.
- Benchmarks would be nice, but this is very obviously a win in perf and
correctness.
---
## Migration Guide
- `Mesh::create_packed_vertex_buffer_data` has been renamed
`Mesh::create_packed_vertex_buffer_data` to reflect the fact that it
copies data and allocates.
## Showcase
- look mom, less copies
# Objective
The `NestedLoader` API as it stands right now is somewhat lacking:
- It consists of several types `NestedLoader`, `UntypedNestedLoader`,
`DirectNestedLoader`, and `UntypedDirectNestedLoader`, where a typestate
pattern on `NestedLoader` would be make it more obvious what it does,
and allow centralising the documentation
- The term "untyped" in the asset loader code is overloaded. It can mean
either:
- we have literally no idea what the type of this asset will be when we
load it (I dub this "unknown type")
- we know what type of asset it will be, but we don't know it statically
- we only have a TypeId (I dub this "dynamic type" / "erased")
- There is no way to get an `UntypedHandle` (erased) given a `TypeId`
## Solution
Changes `NestedLoader` into a type-state pattern, adding two type
params:
- `T` determines the typing
- `StaticTyped`, the default, where you pass in `A` statically into `fn
load<A>() -> ..`
- `DynamicTyped`, where you give a `TypeId`, giving you a
`UntypedHandle`
- `UnknownTyped`, where you have literally no idea what type of asset
you're loading, giving you a `Handle<LoadedUntypedAsset>`
- `M` determines the "mode" (bikeshedding TBD, I couldn't come up with a
better name)
- `Deferred`, the default, won't load the asset when you call `load`,
but it does give you a `Handle` to it (this is nice since it can be a
sync fn)
- `Immediate` will load the asset as soon as you call it, and give you
access to it, but you must be in an async context to call it
Changes some naming of internals in `AssetServer` to fit the new
definitions of "dynamic type" and "unknown type". Note that I didn't do
a full pass over this code to keep the diff small. That can probably be
done in a new PR - I think the definiton I laid out of unknown type vs.
erased makes it pretty clear where each one applies.
<details>
<summary>Old issue</summary>
The only real problem I have with this PR is the requirement to pass in
`type_name` (from `core::any::type_name`) into Erased. Users might not
have that type name, only the ID, and it just seems sort of weird to
*have* to give an asset type name. However, the reason we need it is
because of this:
```rs
pub(crate) fn get_or_create_path_handle_erased(
&mut self,
path: AssetPath<'static>,
type_id: TypeId,
type_name: &str,
loading_mode: HandleLoadingMode,
meta_transform: Option<MetaTransform>,
) -> (UntypedHandle, bool) {
let result = self.get_or_create_path_handle_internal(
path,
Some(type_id),
loading_mode,
meta_transform,
);
// it is ok to unwrap because TypeId was specified above
unwrap_with_context(result, type_name).unwrap()
}
pub(crate) fn unwrap_with_context<T>(
result: Result<T, GetOrCreateHandleInternalError>,
type_name: &str,
) -> Option<T> {
match result {
Ok(value) => Some(value),
Err(GetOrCreateHandleInternalError::HandleMissingButTypeIdNotSpecified) => None,
Err(GetOrCreateHandleInternalError::MissingHandleProviderError(_)) => {
panic!("Cannot allocate an Asset Handle of type '{type_name}' because the asset type has not been initialized. \
Make sure you have called app.init_asset::<{type_name}>()")
}
}
}
```
This `unwrap_with_context` is literally the only reason we need the
`type_name`. Potentially, this can be turned into an `impl
Into<Option<&str>>`, and output a different error message if the type
name is missing. Since if we are loading an asset where we only know the
type ID, by definition we can't output that error message, since we
don't have the type name. I'm open to suggestions on this.
</details>
## Testing
Not sure how to test this, since I kept most of the actual NestedLoader
logic the same. The only new API is loading an `UntypedHandle` when in
the `DynamicTyped, Immediate` state.
## Migration Guide
Code which uses `bevy_asset`'s `LoadContext::loader` / `NestedLoader`
will see some naming changes:
- `untyped` is replaced by `with_unknown_type`
- `with_asset_type` is replaced by `with_static_type`
- `with_asset_type_id` is replaced by `with_dynamic_type`
- `direct` is replaced by `immediate` (the opposite of "immediate" is
"deferred")
# Objective
- This PR fixes#12488
## Solution
- This PR adds a new property to `Camera` that emulates the
functionality of the
[setViewOffset()](https://threejs.org/docs/#api/en/cameras/PerspectiveCamera.setViewOffset)
API in three.js.
- When set, the perspective and orthographic projections will restrict
the visible area of the camera to a part of the view frustum defined by
`offset` and `size`.
## Testing
- In the new `camera_sub_view` example, a fixed, moving and control sub
view is created for both perspective and orthographic projection
- Run the example with `cargo run --example camera_sub_view`
- The code can be tested by adding a `SubCameraView` to a camera
---
## Showcase
![image](https://github.com/user-attachments/assets/75ac45fc-d75d-4664-8ef6-ff7865297c25)
- Left Half: Perspective Projection
- Right Half: Orthographic Projection
- Small boxes in order:
- Sub view of the left half of the full image
- Sub view moving from the top left to the bottom right of the full
image
- Sub view of the full image (acting as a control)
- Large box: No sub view
<details>
<summary>Shortened camera setup of `camera_sub_view` example</summary>
```rust
// Main perspective Camera
commands.spawn(Camera3dBundle {
transform,
..default()
});
// Perspective camera left half
commands.spawn(Camera3dBundle {
camera: Camera {
sub_camera_view: Some(SubCameraView {
// Set the sub view camera to the left half of the full image
full_size: uvec2(500, 500),
offset: ivec2(0, 0),
size: uvec2(250, 500),
}),
order: 1,
..default()
},
transform,
..default()
});
// Perspective camera moving
commands.spawn((
Camera3dBundle {
camera: Camera {
sub_camera_view: Some(SubCameraView {
// Set the sub view camera to a fifth of the full view and
// move it in another system
full_size: uvec2(500, 500),
offset: ivec2(0, 0),
size: uvec2(100, 100),
}),
order: 2,
..default()
},
transform,
..default()
},
MovingCameraMarker,
));
// Perspective camera control
commands.spawn(Camera3dBundle {
camera: Camera {
sub_camera_view: Some(SubCameraView {
// Set the sub view to the full image, to ensure that it matches
// the projection without sub view
full_size: uvec2(450, 450),
offset: ivec2(0, 0),
size: uvec2(450, 450),
}),
order: 3,
..default()
},
transform,
..default()
});
// Main orthographic camera
commands.spawn(Camera3dBundle {
projection: OrthographicProjection {
...
}
.into(),
camera: Camera {
order: 4,
..default()
},
transform,
..default()
});
// Orthographic camera left half
commands.spawn(Camera3dBundle {
projection: OrthographicProjection {
...
}
.into(),
camera: Camera {
sub_camera_view: Some(SubCameraView {
// Set the sub view camera to the left half of the full image
full_size: uvec2(500, 500),
offset: ivec2(0, 0),
size: uvec2(250, 500),
}),
order: 5,
..default()
},
transform,
..default()
});
// Orthographic camera moving
commands.spawn((
Camera3dBundle {
projection: OrthographicProjection {
...
}
.into(),
camera: Camera {
sub_camera_view: Some(SubCameraView {
// Set the sub view camera to a fifth of the full view and
// move it in another system
full_size: uvec2(500, 500),
offset: ivec2(0, 0),
size: uvec2(100, 100),
}),
order: 6,
..default()
},
transform,
..default()
},
MovingCameraMarker,
));
// Orthographic camera control
commands.spawn(Camera3dBundle {
projection: OrthographicProjection {
...
}
.into(),
camera: Camera {
sub_camera_view: Some(SubCameraView {
// Set the sub view to the full image, to ensure that it matches
// the projection without sub view
full_size: uvec2(450, 450),
offset: ivec2(0, 0),
size: uvec2(450, 450),
}),
order: 7,
..default()
},
transform,
..default()
});
```
</details>
# Objective
- Fixes#9968
## Solution
- Uses
[open_dir](https://docs.rs/ndk/latest/ndk/asset/struct.AssetManager.html#method.open_dir)
to read directories and collects child list, since it can't be shared
across threads.
- For `is_directory`, uses result of
[open](https://docs.rs/ndk/latest/ndk/asset/struct.AssetManager.html#method.open),
which will fail for directories. I tried using the result of `open_dir`
for this, but it was successful for files too, which made loading
folders return empty lists, since `open_dir` was successful and treated
all files as empty directories.
- Ignoring `meta` files was copied from filesystem implementation
---
## Changelog
- Fixed: Android's AssetReader implementation now supports
read_directory and is_directory.
## Notes
I noticed late that there was the #9968 issue (I only noticed #9591), so
I have also missed that a PR was already open (#9969). Feel free to copy
over the fixes from this one over there.
The only difference I notice between these 2, is that I have used `open`
instead of `open_dir` for `is_directory` implementation. I have tried
with `open_dir` too, but unfortunately that didn't work. I tested this
on an actual device, using the mobile example, by making some minor
changes:
```rust
#[derive(Resource)]
struct FolderAssets(Handle<LoadedFolder>);
// the `bevy_main` proc_macro generates the required boilerplate for iOS and Android
#[bevy_main]
fn main() {
// ...
.add_systems(Startup, (setup_scene, load_music_files))
.add_systems(
Update,
// Removed the handle_lifetime since AudioBundle is added later
(touch_camera, button_handler, setup_music),
);
// ...
}
fn load_music_files(asset_server: Res<AssetServer>, mut commands: Commands) {
let sounds = asset_server.load_folder("sounds");
commands.insert_resource(FolderAssets(sounds));
}
fn setup_music(
mut commands: Commands,
folders: Res<Assets<LoadedFolder>>,
mut loaded_event: EventReader<AssetEvent<LoadedFolder>>,
) {
for event in loaded_event.read() {
if let AssetEvent::LoadedWithDependencies { id } = event {
if let Some(folder) = folders.get(*id) {
warn!("Folder items: {:?}", folder.handles);
if let Some(source) = folder.handles.first() {
commands.spawn(AudioBundle {
source: source.clone().typed::<AudioSource>(),
settings: PlaybackSettings::LOOP,
});
}
}
}
}
}
```
---------
Co-authored-by: Kanabenki <lucien.menassol@gmail.com>
Co-authored-by: François Mockers <francois.mockers@vleue.com>
# Objective
The primary motivation behind this PR is to (partially?) address the
limitations imposed by the recently added `AsyncSeek` trait bound
discussed in issue #12880. While the `AsyncSeek` trait add some
flexibility to the reader, it inadvertently restricts the ability to
write asset readers that can truly stream bytes, particularly in
scenarios like HTTP requests where backward seeking is not supported. It
is also challenging in contexts where assets are stored in compressed
formats or require other kinds of transformations.
The logic behind this change is that currently, with `AsyncSeek`, an
asset Reader based on streamed data will either 1) fail silently, 2)
return an error, or 3) use a buffer to satisfy the trait constraint. I
believe that being able to advance in the file without having to "read"
it is a good thing. The only issue here is the ability to seek backward.
It is highly likely that in this context, we only need to seek forward
in the file because we would have already read an entry table upstream
and just want to access one or more resources further in the file. I
understand that in some cases, this may not be applicable, but I think
it is more beneficial not to constrain `Reader`s that want to stream
than to allow "Assets" to read files in a completely arbitrary order.
## Solution
Replace the current `AsyncSeek` trait with `AsyncSeekForward` on asset
`Reader`
## Changelog
- Introduced a new custom trait, `AsyncSeekForward`, for the asset
Reader.
- Replaced the current `AsyncSeek` trait with `AsyncSeekForward` for all
asset `Reader` implementations.
## Migration Guide
Replace all instances of `AsyncSeek` with `AsyncSeekForward` in your
asset reader implementations.
# Objective
Another step in the migration to required components: lights!
Note that this does not include `EnvironmentMapLight` or reflection
probes yet, because their API hasn't been fully chosen yet.
## Solution
As per the [selected
proposals](https://hackmd.io/@bevy/required_components/%2FLLnzwz9XTxiD7i2jiUXkJg):
- Deprecate `PointLightBundle` in favor of the `PointLight` component
- Deprecate `SpotLightBundle` in favor of the `PointLight` component
- Deprecate `DirectionalLightBundle` in favor of the `DirectionalLight`
component
## Testing
I ran some examples with lights.
---
## Migration Guide
`PointLightBundle`, `SpotLightBundle`, and `DirectionalLightBundle` have
been deprecated. Use the `PointLight`, `SpotLight`, and
`DirectionalLight` components instead. Adding them will now insert the
other components required by them automatically.
# Objective
Fixes#15540
End-users risk using `World::flush_commands` instead of `World::flush`,
which panics if any queued commands are `spawn`. Hiding
`World::flush_commands` would help avoid calling a potentially panicky
function, and helps alleviate end-user API confusion.
## Solution
This PR updates the function visibility to crate-level, like
`World::flush_entities`, hiding it from the end-user while still making
it accessible for the tests that are currently set up.
## Testing
The change was tested by executing the available tests for `bevy_ecs`.
From what I've gathered, `World::flush_commands` is not used in any
other bevy crate. If further testing is recommended, please inform me!
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
# Objective
Fixes#15541
A bunch of lifetimes were added during the Assets V2 rework, but after
moving to async traits in #12550 they can be elided. That PR mentions
that this might be the case, but apparently it wasn't followed up on at
the time.
~~I ended up grepping for `<'a` and finding a similar case in
`bevy_reflect` which I also fixed.~~ (edit: that one was needed
apparently)
Note that elided lifetimes are unstable in `impl Trait`. If that gets
stabilized then we can elide even more.
## Solution
Remove the extra lifetimes.
## Testing
Everything still compiles. If I have messed something up there is a
small risk that some user code stops compiling, but all the examples
still work at least.
---
## Migration Guide
The traits `AssetLoader`, `AssetSaver` and `Process` traits from
`bevy_asset` now use elided lifetimes. If you implement these then
remove the named lifetime.
# Objective
This PR extends and reworks the material from #15282 by allowing
arbitrary curves to be used by the animation system to animate arbitrary
properties. The goals of this work are to:
- Allow far greater flexibility in how animations are allowed to be
defined in order to be used with `bevy_animation`.
- Delegate responsibility over keyframe interpolation to `bevy_math` and
the `Curve` libraries and reduce reliance on keyframes in animation
definitions generally.
- Move away from allowing the glTF spec to completely define animations
on a mechanical level.
## Solution
### Overview
At a high level, curves have been incorporated into the animation system
using the `AnimationCurve` trait (closely related to what was
`Keyframes`). From the top down:
1. In `animate_targets`, animations are driven by `VariableCurve`, which
is now a thin wrapper around a `Box<dyn AnimationCurve>`.
2. `AnimationCurve` is something built out of a `Curve`, and it tells
the animation system how to use the curve's output to actually mutate
component properties. The trait looks like this:
```rust
/// A low-level trait that provides control over how curves are actually applied to entities
/// by the animation system.
///
/// Typically, this will not need to be implemented manually, since it is automatically
/// implemented by [`AnimatableCurve`] and other curves used by the animation system
/// (e.g. those that animate parts of transforms or morph weights). However, this can be
/// implemented manually when `AnimatableCurve` is not sufficiently expressive.
///
/// In many respects, this behaves like a type-erased form of [`Curve`], where the output
/// type of the curve is remembered only in the components that are mutated in the
/// implementation of [`apply`].
///
/// [`apply`]: AnimationCurve::apply
pub trait AnimationCurve: Reflect + Debug + Send + Sync {
/// Returns a boxed clone of this value.
fn clone_value(&self) -> Box<dyn AnimationCurve>;
/// The range of times for which this animation is defined.
fn domain(&self) -> Interval;
/// Write the value of sampling this curve at time `t` into `transform` or `entity`,
/// as appropriate, interpolating between the existing value and the sampled value
/// using the given `weight`.
fn apply<'a>(
&self,
t: f32,
transform: Option<Mut<'a, Transform>>,
entity: EntityMutExcept<'a, (Transform, AnimationPlayer, Handle<AnimationGraph>)>,
weight: f32,
) -> Result<(), AnimationEvaluationError>;
}
```
3. The conversion process from a `Curve` to an `AnimationCurve` involves
using wrappers which communicate the intent to animate a particular
property. For example, here is `TranslationCurve`, which wraps a
`Curve<Vec3>` and uses it to animate `Transform::translation`:
```rust
/// This type allows a curve valued in `Vec3` to become an [`AnimationCurve`] that animates
/// the translation component of a transform.
pub struct TranslationCurve<C>(pub C);
```
### Animatable Properties
The `AnimatableProperty` trait survives in the transition, and it can be
used to allow curves to animate arbitrary component properties. The
updated documentation for `AnimatableProperty` explains this process:
<details>
<summary>Expand AnimatableProperty example</summary
An `AnimatableProperty` is a value on a component that Bevy can animate.
You can implement this trait on a unit struct in order to support
animating
custom components other than transforms and morph weights. Use that type
in
conjunction with `AnimatableCurve` (and perhaps
`AnimatableKeyframeCurve`
to define the animation itself). For example, in order to animate font
size of a
text section from 24 pt. to 80 pt., you might use:
```rust
#[derive(Reflect)]
struct FontSizeProperty;
impl AnimatableProperty for FontSizeProperty {
type Component = Text;
type Property = f32;
fn get_mut(component: &mut Self::Component) -> Option<&mut Self::Property> {
Some(&mut component.sections.get_mut(0)?.style.font_size)
}
}
```
You can then create an `AnimationClip` to animate this property like so:
```rust
let mut animation_clip = AnimationClip::default();
animation_clip.add_curve_to_target(
animation_target_id,
AnimatableKeyframeCurve::new(
[
(0.0, 24.0),
(1.0, 80.0),
]
)
.map(AnimatableCurve::<FontSizeProperty, _>::from_curve)
.expect("Failed to create font size curve")
);
```
Here, the use of `AnimatableKeyframeCurve` creates a curve out of the
given keyframe time-value
pairs, using the `Animatable` implementation of `f32` to interpolate
between them. The
invocation of `AnimatableCurve::from_curve` with `FontSizeProperty`
indicates that the `f32`
output from that curve is to be used to animate the font size of a
`Text` component (as
configured above).
</details>
### glTF Loading
glTF animations are now loaded into `Curve` types of various kinds,
depending on what is being animated and what interpolation mode is being
used. Those types get wrapped into and converted into `Box<dyn
AnimationCurve>` and shoved inside of a `VariableCurve` just like
everybody else.
### Morph Weights
There is an `IterableCurve` abstraction which allows sampling these from
a contiguous buffer without allocating. Its only reason for existing is
that Rust disallows you from naming function types, otherwise we would
just use `Curve` with an iterator output type. (The iterator involves
`Map`, and the name of the function type would have to be able to be
named, but it is not.)
A `WeightsCurve` adaptor turns an `IterableCurve` into an
`AnimationCurve`, so it behaves like everything else in that regard.
## Testing
Tested by running existing animation examples. Interpolation logic has
had additional tests added within the `Curve` API to replace the tests
in `bevy_animation`. Some kinds of out-of-bounds errors have become
impossible.
Performance testing on `many_foxes` (`animate_targets`) suggests that
performance is very similar to the existing implementation. Here are a
couple trace histograms across different runs (yellow is this branch,
red is main).
<img width="669" alt="Screenshot 2024-09-27 at 9 41 50 AM"
src="https://github.com/user-attachments/assets/5ba4e9ac-3aea-452e-aaf8-1492acc2d7fc">
<img width="673" alt="Screenshot 2024-09-27 at 9 45 18 AM"
src="https://github.com/user-attachments/assets/8982538b-04cf-46b5-97b2-164c6bc8162e">
---
## Migration Guide
Most user code that does not directly deal with `AnimationClip` and
`VariableCurve` will not need to be changed. On the other hand,
`VariableCurve` has been completely overhauled. If you were previously
defining animation curves in code using keyframes, you will need to
migrate that code to use curve constructors instead. For example, a
rotation animation defined using keyframes and added to an animation
clip like this:
```rust
animation_clip.add_curve_to_target(
animation_target_id,
VariableCurve {
keyframe_timestamps: vec![0.0, 1.0, 2.0, 3.0, 4.0],
keyframes: Keyframes::Rotation(vec![
Quat::IDENTITY,
Quat::from_axis_angle(Vec3::Y, PI / 2.),
Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.),
Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.),
Quat::IDENTITY,
]),
interpolation: Interpolation::Linear,
},
);
```
would now be added like this:
```rust
animation_clip.add_curve_to_target(
animation_target_id,
AnimatableKeyframeCurve::new([0.0, 1.0, 2.0, 3.0, 4.0].into_iter().zip([
Quat::IDENTITY,
Quat::from_axis_angle(Vec3::Y, PI / 2.),
Quat::from_axis_angle(Vec3::Y, PI / 2. * 2.),
Quat::from_axis_angle(Vec3::Y, PI / 2. * 3.),
Quat::IDENTITY,
]))
.map(RotationCurve)
.expect("Failed to build rotation curve"),
);
```
Note that the interface of `AnimationClip::add_curve_to_target` has also
changed (as this example shows, if subtly), and now takes its curve
input as an `impl AnimationCurve`. If you need to add a `VariableCurve`
directly, a new method `add_variable_curve_to_target` accommodates that
(and serves as a one-to-one migration in this regard).
### For reviewers
The diff is pretty big, and the structure of some of the changes might
not be super-obvious:
- `keyframes.rs` became `animation_curves.rs`, and `AnimationCurve` is
based heavily on `Keyframes`, with the adaptors also largely following
suite.
- The Curve API adaptor structs were moved from `bevy_math::curve::mod`
into their own module `adaptors`. There are no functional changes to how
these adaptors work; this is just to make room for the specialized
reflection implementations since `mod.rs` was getting kind of cramped.
- The new module `gltf_curves` holds the additional curve constructions
that are needed by the glTF loader. Note that the loader uses a mix of
these and off-the-shelf `bevy_math` curve stuff.
- `animatable.rs` no longer holds logic related to keyframe
interpolation, which is now delegated to the existing abstractions in
`bevy_math::curve::cores`.
---------
Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com>
Co-authored-by: aecsocket <43144841+aecsocket@users.noreply.github.com>
# Objective
Fixes#15367.
Currently, required components can only be defined through the `require`
macro attribute. While this should be used in most cases, there are also
several instances where you may want to define requirements at runtime,
commonly in plugins.
Example use cases:
- Require components only if the relevant optional plugins are enabled.
For example, a `SleepTimer` component (for physics) is only relevant if
the `SleepPlugin` is enabled.
- Third party crates can define their own requirements for first party
types. For example, "each `Handle<Mesh>` should require my custom
rendering data components". This also gets around the orphan rule.
- Generic plugins that add marker components based on the existence of
other components, like a generic `ColliderPlugin<C: AnyCollider>` that
wants to add a `ColliderMarker` component for all types of colliders.
- This is currently relevant for the retained render world in #15320.
The `ExtractComponentPlugin<C>` should add `SyncToRenderWorld` to all
components that should be extracted. This is currently done with
observers, which is more expensive than required components, and causes
archetype moves.
- Replace some built-in components with custom versions. For example, if
`GlobalTransform` required `Transform` through `TransformPlugin`, but we
wanted to use a `CustomTransform` type, we could replace
`TransformPlugin` with our own plugin. (This specific example isn't
good, but there are likely better use cases where this may be useful)
See #15367 for more in-depth reasoning.
## Solution
Add `register_required_components::<T, R>` and
`register_required_components_with::<T, R>` methods for `Default` and
custom constructors respectively. These methods exist on `App` and
`World`.
```rust
struct BirdPlugin;
impl Plugin for BirdPlugin {
fn plugin(app: &mut App) {
// Make `Bird` require `Wings` with a `Default` constructor.
app.register_required_components::<Bird, Wings>();
// Make `Wings` require `FlapSpeed` with a custom constructor.
// Fun fact: Some hummingbirds can flutter their wings 80 times per second!
app.register_required_components_with::<Wings, FlapSpeed>(|| FlapSpeed::from_duration(1.0 / 80.0));
}
}
```
The custom constructor is a function pointer to match the `require` API,
though it could take a raw value too.
Requirement inheritance works similarly as with the `require` attribute.
If `Bird` required `FlapSpeed` directly, it would take precedence over
indirectly requiring it through `Wings`. The same logic applies to all
levels of the inheritance tree.
Note that registering the same component requirement more than once will
panic, similarly to trying to add multiple component hooks of the same
type to the same component. This avoids constructor conflicts and
confusing ordering issues.
### Implementation
Runtime requirements have two additional challenges in comparison to the
`require` attribute.
1. The `require` attribute uses recursion and macros with clever
ordering to populate hash maps of required components for each component
type. The expected semantics are that "more specific" requirements
override ones deeper in the inheritance tree. However, at runtime, there
is no representation of how "specific" each requirement is.
2. If you first register the requirement `X -> Y`, and later register `Y
-> Z`, then `X` should also indirectly require `Z`. However, `Y` itself
doesn't know that it is required by `X`, so it's not aware that it
should update the list of required components for `X`.
My solutions to these problems are:
1. Store the depth in the inheritance tree for each entry of a given
component's `RequiredComponents`. This is used to determine how
"specific" each requirement is. For `require`-based registration, these
depths are computed as part of the recursion.
2. Store and maintain a `required_by` list in each component's
`ComponentInfo`, next to `required_components`. For `require`-based
registration, these are also added after each registration, as part of
the recursion.
When calling `register_required_components`, it works as follows:
1. Get the required components of `Foo`, and check that `Bar` isn't
already a *direct* requirement.
3. Register `Bar` as a required component for `Foo`, and add `Foo` to
the `required_by` list for `Bar`.
4. Find and register all indirect requirements inherited from `Bar`,
adding `Foo` to the `required_by` list for each component.
5. Iterate through components that require `Foo`, registering the new
inherited requires for them as indirect requirements.
The runtime registration is likely slightly more expensive than the
`require` version, but it is a one-time cost, and quite negligible in
practice, unless projects have hundreds or thousands of runtime
requirements. I have not benchmarked this however.
This does also add a small amount of extra cost to the `require`
attribute for updating `required_by` lists, but I expect it to be very
minor.
## Testing
I added some tests that are copies of the `require` versions, as well as
some tests that are more specific to the runtime implementation. I might
add a few more tests though.
## Discussion
- Is `register_required_components` a good name? Originally I went for
`register_component_requirement` to be consistent with
`register_component_hooks`, but the general feature is often referred to
as "required components", which is why I changed it to
`register_required_components`.
- Should we *not* panic for duplicate requirements? If so, should they
just be ignored, or should the latest registration overwrite earlier
ones?
- If we do want to panic for duplicate, conflicting registrations,
should we at least not panic if the registrations are *exactly* the
same, i.e. same component and same constructor? The current
implementation panics for all duplicate direct registrations regardless
of the constructor.
## Next Steps
- Allow `register_required_components` to take a `Bundle` instead of a
single required component.
- I could also try to do it in this PR if that would be preferable.
- Not directly related, but archetype invariants?
- Adopted from #14449
- Still fixes#12144.
## Migration Guide
The retained render world is a complex change: migrating might take one
of a few different forms depending on the patterns you're using.
For every example, we specify in which world the code is run. Most of
the changes affect render world code, so for the average Bevy user who's
using Bevy's high-level rendering APIs, these changes are unlikely to
affect your code.
### Spawning entities in the render world
Previously, if you spawned an entity with `world.spawn(...)`,
`commands.spawn(...)` or some other method in the rendering world, it
would be despawned at the end of each frame. In 0.15, this is no longer
the case and so your old code could leak entities. This can be mitigated
by either re-architecting your code to no longer continuously spawn
entities (like you're used to in the main world), or by adding the
`bevy_render::world_sync::TemporaryRenderEntity` component to the entity
you're spawning. Entities tagged with `TemporaryRenderEntity` will be
removed at the end of each frame (like before).
### Extract components with `ExtractComponentPlugin`
```
// main world
app.add_plugins(ExtractComponentPlugin::<ComponentToExtract>::default());
```
`ExtractComponentPlugin` has been changed to only work with synced
entities. Entities are automatically synced if `ComponentToExtract` is
added to them. However, entities are not "unsynced" if any given
`ComponentToExtract` is removed, because an entity may have multiple
components to extract. This would cause the other components to no
longer get extracted because the entity is not synced.
So be careful when only removing extracted components from entities in
the render world, because it might leave an entity behind in the render
world. The solution here is to avoid only removing extracted components
and instead despawn the entire entity.
### Manual extraction using `Extract<Query<(Entity, ...)>>`
```rust
// in render world, inspired by bevy_pbr/src/cluster/mod.rs
pub fn extract_clusters(
mut commands: Commands,
views: Extract<Query<(Entity, &Clusters, &Camera)>>,
) {
for (entity, clusters, camera) in &views {
// some code
commands.get_or_spawn(entity).insert(...);
}
}
```
One of the primary consequences of the retained rendering world is that
there's no longer a one-to-one mapping from entity IDs in the main world
to entity IDs in the render world. Unlike in Bevy 0.14, Entity 42 in the
main world doesn't necessarily map to entity 42 in the render world.
Previous code which called `get_or_spawn(main_world_entity)` in the
render world (`Extract<Query<(Entity, ...)>>` returns main world
entities). Instead, you should use `&RenderEntity` and
`render_entity.id()` to get the correct entity in the render world. Note
that this entity does need to be synced first in order to have a
`RenderEntity`.
When performing manual abstraction, this won't happen automatically
(like with `ExtractComponentPlugin`) so add a `SyncToRenderWorld` marker
component to the entities you want to extract.
This results in the following code:
```rust
// in render world, inspired by bevy_pbr/src/cluster/mod.rs
pub fn extract_clusters(
mut commands: Commands,
views: Extract<Query<(&RenderEntity, &Clusters, &Camera)>>,
) {
for (render_entity, clusters, camera) in &views {
// some code
commands.get_or_spawn(render_entity.id()).insert(...);
}
}
// in main world, when spawning
world.spawn(Clusters::default(), Camera::default(), SyncToRenderWorld)
```
### Looking up `Entity` ids in the render world
As previously stated, there's now no correspondence between main world
and render world `Entity` identifiers.
Querying for `Entity` in the render world will return the `Entity` id in
the render world: query for `MainEntity` (and use its `id()` method) to
get the corresponding entity in the main world.
This is also a good way to tell the difference between synced and
unsynced entities in the render world, because unsynced entities won't
have a `MainEntity` component.
---------
Co-authored-by: re0312 <re0312@outlook.com>
Co-authored-by: re0312 <45868716+re0312@users.noreply.github.com>
Co-authored-by: Periwink <charlesbour@gmail.com>
Co-authored-by: Anselmo Sampietro <ans.samp@gmail.com>
Co-authored-by: Emerson Coskey <56370779+ecoskey@users.noreply.github.com>
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: Christian Hughes <9044780+ItsDoot@users.noreply.github.com>
# Objective
Unlike `Capsule3d` which has the `.to_cylinder` method, `Capsule2d`
doesn't have an equivalent `.to_inner_rectangle` method and as shown by
#15191 this is surprisingly easy to get wrong
## Solution
Implemented a `Capsule2d::to_inner_rectangle` method as it is
implemented in the fixed `Capsule2d` shape sampling, and as I was adding
tests I noticed `Capsule2d` didn't implement `Measure2d` so I did this
as well.
## Changelog
### Added
- `Capsule2d::to_inner_rectangle`, `Capsule2d::area` and
`Capsule2d::perimeter`
---------
Co-authored-by: Joona Aalto <jondolf.dev@gmail.com>
Co-authored-by: James Liu <contact@jamessliu.com>
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
# Objective
`ui_stack_system` generates a tree of `StackingContexts` which it then
flattens to get the `UiStack`.
But there's no need to construct a new tree. We can query for nodes with
a global `ZIndex`, add those nodes to the root nodes list and then build
the `UiStack` from a walk of the existing layout tree, ignoring any
branches that have a global `Zindex`.
Fixes#9877
## Solution
Split the `ZIndex` enum into two separate components, `ZIndex` and
`GlobalZIndex`
Query for nodes with a `GlobalZIndex`, add those nodes to the root nodes
list and then build the `UiStack` from a walk of the existing layout
tree, filtering branches by `Without<GlobalZIndex>` so we don't revisit
nodes.
```
cargo run --profile stress-test --features trace_tracy --example many_buttons
```
<img width="672" alt="ui-stack-system-walk-split-enum"
src="https://github.com/bevyengine/bevy/assets/27962798/11e357a5-477f-4804-8ada-c4527c009421">
(Yellow is this PR, red is main)
---
## Changelog
`Zindex`
* The `ZIndex` enum has been split into two separate components `ZIndex`
(which replaces `ZIndex::Local`) and `GlobalZIndex` (which replaces
`ZIndex::Global`). An entity can have both a `ZIndex` and
`GlobalZIndex`, in comparisons `ZIndex` breaks ties if two
`GlobalZIndex` values are equal.
`ui_stack_system`
* Instead of generating a tree of `StackingContexts`, query for nodes
with a `GlobalZIndex`, add those nodes to the root nodes list and then
build the `UiStack` from a walk of the existing layout tree, filtering
branches by `Without<GlobalZIndex` so we don't revisit nodes.
## Migration Guide
The `ZIndex` enum has been split into two separate components `ZIndex`
(which replaces `ZIndex::Local`) and `GlobalZIndex` (which replaces
`ZIndex::Global`). An entity can have both a `ZIndex` and
`GlobalZIndex`, in comparisons `ZIndex` breaks ties if two
`GlobalZindex` values are equal.
---------
Co-authored-by: Gabriel Bourgeois <gabriel.bourgeoisv4si@gmail.com>
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
Co-authored-by: UkoeHB <37489173+UkoeHB@users.noreply.github.com>
(Note: #15434 implements something very similar to this for functional
curve adaptors, which is why they aren't present in this PR.)
# Objective
Previously, there was basically no chance that the
explicitly-interpolating sample curve structs from the `Curve` API would
actually be `Reflect`. The reason for this is functional programming:
the structs contain an explicit interpolation `I: Fn(&T, &T, f32) -> T`
which, under typical circumstances, will never be `Reflect`, which
prevents the derive from realistically succeeding. In fact, they won't
be a lot of other things either, notably including both`Debug` and
`TypePath`, which are also required for reflection to succeed.
The goal of this PR is to weaken the implementations of reflection
traits for these structs so that they can implement `Reflect` under
reasonable circumstances. (Notably, they will still not be
`FromReflect`, which is unavoidable.)
## Solution
The function fields are marked as `#[reflect(ignore)]`, and the derive
macro for `Reflect` has `FromReflect` disabled. (This is not fully
optimal, but we don't presently have any kind of "read-only" attribute
for these fields.) Additionally, these structs receive custom `Debug`
and `TypePath` implementations that display the function's (unstable!)
type name instead of its value or type path (respectively). In the case
of `TypePath`, this is a bit janky, but the instability of `type_name`
won't generally present an issue for generics, which would have to be
registered manually in the type registry anyway, which is impossible
because the function type parameters cannot be named.
(And in general, the "blessed" route for such cases would generally
involve manually monomorphizing the function parameter away, which also
allows access to `FromReflect` etc. through very ordinary use of the
derive macro.)
## Testing
Tests in the new `bevy_math::curve::sample_curves` module guarantee that
these are actually `Reflect` under reasonable circumstances.
---
## Future changes
If and when function item types become `Default`, these types will need
to receive custom `FromReflect` implementations that exploit it. Such a
custom implementation would also be desirable if users start doing
things like wrapping function items in `Default`/`FromReflect` wrappers
that still implement a `Fn` trait.
Additionally, if function types become nameable in user-space, the
stance on `Debug`/`TypePath` may bear reexamination, since partial
monomorphization through wrappers would make implementing reflect traits
for function types potentially more viable.
---------
Co-authored-by: Gino Valente <49806985+MrGVSV@users.noreply.github.com>
# Objective
Fix#12273
## Solution
– Only emit `KeyboardFocusLost` when the keyboard focus is lost
– ignore synthetic key releases too, not just key presses (as they're
already covered by `KeyboardFocusLost`)
---
## Changelog
### Fixed
- Don't trigger `ButtonInput<KeyCode>::just_pressed`/`just_released`
when spawning a window/focus moving between Bevy windows
# Objective
- Contributes to #15460
- Allows `bevy_mikktspace` to be used in `no_std` contexts.
## Solution
- Added `std` (default) and `libm` features which control the inclusion
of the standard library. To use `bevy_mikktspace` in `no_std`
environments, enable the `libm` feature.
## Testing
- CI
- `cargo clippy -p bevy_mikktspace --target "x86_64-unknown-none"
--no-default-features --features libm`
# Objective
Add a `Populated` system parameter that acts like `Query`, but prevents
system from running if there are no matching entities.
Fixes: #15302
## Solution
Implement the system param which newtypes the `Query`.
The only change is new validation, which fails if query is empty.
The new system param is used in `fallible_params` example.
## Testing
Ran `fallible_params` example.
---------
Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com>
# Objective
Currently, reflecting a generic type provides no information about the
generic parameters. This means that you can't get access to the type of
`T` in `Foo<T>` without creating custom type data (we do this for
[`ReflectHandle`](https://docs.rs/bevy/0.14.2/bevy/asset/struct.ReflectHandle.html#method.asset_type_id)).
## Solution
This PR makes it so that generic type parameters and generic const
parameters are tracked in a `Generics` struct stored on the `TypeInfo`
for a type.
For example, `struct Foo<T, const N: usize>` will store `T` and `N` as a
`TypeParamInfo` and `ConstParamInfo`, respectively.
The stored information includes:
- The name of the generic parameter (i.e. `T`, `N`, etc.)
- The type of the generic parameter (remember that we're dealing with
monomorphized types, so this will actually be a concrete type)
- The default type/value, if any (e.g. `f32` in `T = f32` or `10` in
`const N: usize = 10`)
### Caveats
The only requirement for this to work is that the user does not opt-out
of the automatic `TypePath` derive with `#[reflect(type_path = false)]`.
Doing so prevents the macro code from 100% knowing that the generic type
implements `TypePath`. This in turn means the generated `Typed` impl
can't add generics to the type.
There are two solutions for this—both of which I think we should explore
in a future PR:
1. We could just not use `TypePath`. This would mean that we can't store
the `Type` of the generic, but we can at least store the `TypeId`.
2. We could provide a way to opt out of the automatic `Typed` derive
with a `#[reflect(typed = false)]` attribute. This would allow users to
manually implement `Typed` to add whatever generic information they need
(e.g. skipping a parameter that can't implement `TypePath` while the
rest can).
I originally thought about making `Generics` an enum with `Generic`,
`NonGeneric`, and `Unavailable` variants to signify whether there are
generics, no generics, or generics that cannot be added due to opting
out of `TypePath`. I ultimately decided against this as I think it adds
a bit too much complexity for such an uncommon problem.
Additionally, user's don't necessarily _have_ to know the generics of a
type, so just skipping them should generally be fine for now.
## Testing
You can test locally by running:
```
cargo test --package bevy_reflect
```
---
## Showcase
You can now access generic parameters via `TypeInfo`!
```rust
#[derive(Reflect)]
struct MyStruct<T, const N: usize>([T; N]);
let generics = MyStruct::<f32, 10>::type_info().generics();
// Get by index:
let t = generics.get(0).unwrap();
assert_eq!(t.name(), "T");
assert!(t.ty().is::<f32>());
assert!(!t.is_const());
// Or by name:
let n = generics.get_named("N").unwrap();
assert_eq!(n.name(), "N");
assert!(n.ty().is::<usize>());
assert!(n.is_const());
```
You can even access parameter defaults:
```rust
#[derive(Reflect)]
struct MyStruct<T = String, const N: usize = 10>([T; N]);
let generics = MyStruct::<f32, 5>::type_info().generics();
let GenericInfo::Type(info) = generics.get_named("T").unwrap() else {
panic!("expected a type parameter");
};
let default = info.default().unwrap();
assert!(default.is::<String>());
let GenericInfo::Const(info) = generics.get_named("N").unwrap() else {
panic!("expected a const parameter");
};
let default = info.default().unwrap();
assert_eq!(default.downcast_ref::<usize>().unwrap(), &10);
```
# Objective
We introduced the fancy Curve API earlier in this version. The goal of
this PR is to provide a level of integration between that API and the
existing spline constructions in `bevy_math`.
Note that this PR only covers the integration of position-sampling via
the `Curve` API. Other (substantially more complex) planned work will
introduce general facilities for handling derivatives.
## Solution
`CubicSegment`, `CubicCurve`, `RationalSegment`, and `RationalCurve` all
now implement `Curve`, using their `position` function to sample the
output.
Additionally, some documentation has been updated/corrected, and
`Serialize`/`Deserialize` derives have been added for all the curve
structs. (Note that there are some barriers to automatic registration of
`ReflectSerialize`/`ReflectSerialize` involving generics that have not
been resolved in this PR.)
---
## Migration Guide
The `RationalCurve::domain` method has been renamed to
`RationalCurve::length`. Calling `.domain()` on a `RationalCurve` now
returns its entire domain as an `Interval`.
# Objective
- The shader_instancing example can be misleading since it doesn't
explain that bevy has built in automatic instancing.
## Solution
- Explain that bevy has built in instancing and that this example is for
advanced users.
- Add a new automatic_instancing example that shows how to use the built
in automatic instancing
- Rename the shader_instancing example to custom_shader_instancing to
highlight that this is a more advanced implementation
---------
Co-authored-by: JMS55 <47158642+JMS55@users.noreply.github.com>
# Objective
* Remove all uses of render_resource_wrapper.
* Make it easier to share a `wgpu::Device` between Bevy and application
code.
## Solution
Removed the `render_resource_wrapper` macro.
To improve the `RenderCreation:: Manual ` API, `ErasedRenderDevice` was
replaced by `Arc`. Unfortunately I had to introduce one more usage of
`WgpuWrapper` which seems like an unwanted constraint on the caller.
## Testing
- Did you test these changes? If so, how?
- Ran `cargo test`.
- Ran a few examples.
- Used `RenderCreation::Manual` in my own project
- Exercised `RenderCreation::Automatic` through examples
- Are there any parts that need more testing?
- No
- How can other people (reviewers) test your changes? Is there anything
specific they need to know?
- Run examples
- Use `RenderCreation::Manual` in their own project
# Objective
- Provide a generic and _reflectable_ way to iterate over contained
entities
## Solution
Adds two new traits:
* `VisitEntities`: Reflectable iteration, accepts a closure rather than
producing an iterator. Implemented by default for `IntoIterator`
implementing types. A proc macro is also provided.
* A `Mut` variant of the above. Its derive macro uses the same field
attribute to avoid repetition.
## Testing
Added a test for `VisitEntities` that also transitively tests its derive
macro as well as the default `MapEntities` impl.
# Objective
Adds a new `Readback` component to request for readback of a
`Handle<Image>` or `Handle<ShaderStorageBuffer>` to the CPU in a future
frame.
## Solution
We track the `Readback` component and allocate a target buffer to write
the gpu resource into and map it back asynchronously, which then fires a
trigger on the entity in the main world. This proccess is asynchronous,
and generally takes a few frames.
## Showcase
```rust
let mut buffer = ShaderStorageBuffer::from(vec![0u32; 16]);
buffer.buffer_description.usage |= BufferUsages::COPY_SRC;
let buffer = buffers.add(buffer);
commands
.spawn(Readback::buffer(buffer.clone()))
.observe(|trigger: Trigger<ReadbackComplete>| {
info!("Buffer data from previous frame {:?}", trigger.event());
});
```
---------
Co-authored-by: Kristoffer Søholm <k.soeholm@gmail.com>
Co-authored-by: IceSentry <IceSentry@users.noreply.github.com>
# Objective
`World::flush_commands` will cause a panic with `error[B0003]: Could not
insert a bundle [...] for entity [...] because it doesn't exist in this
World` if there was a `spawn` command in the queue and you should
instead use `flush` for this but this isn't mentioned in the docs
## Solution
Add a note to the docs suggesting to use `World::flush` in this context.
This error doesn't appear to happen with `spawn_batch` so I didn't add
that to the note although you can cause it with
`commands.spawn_empty().insert(...)` but I wasn't sure that was worth
the documentation complexity as it is pretty unlikely (and equivalent to
`commands.spawn(...)`.
# Objective
Fixes#15185.
# Solution
Change `drain` to take a `&mut self` for most reflected types.
Some notable exceptions to this change are `Array` and `Tuple`. These
types don't make sense with `drain` taking a mutable borrow since they
can't get "smaller". Also `BTreeMap` doesn't have a `drain` function, so
we have to pop elements off one at a time.
## Testing
- The existing tests are sufficient.
---
## Migration Guide
- `reflect::Map`, `reflect::List`, and `reflect::Set` all now take a
`&mut self` instead of a `Box<Self>`. Callers of these traits should add
`&mut` before their boxes, and implementers of these traits should
update to match.
# Objective
Mostly covers the first point in
https://github.com/bevyengine/bevy/issues/13713#issuecomment-2364786694
The idea here is that a lot of people want to load their own texture
atlases, and many of them do this by deserializing some custom version
of `TextureAtlasLayout`. This makes that a little easier by providing
`serde` impls for them.
## Solution
In order to make `TextureAtlasLayout` serializable, the custom texture
mappings that are added by `TextureAtlasBuilder` were separated into
their own type, `TextureAtlasSources`. The inner fields are made public
so people can create their own version of this type, although because it
embeds asset IDs, it's not as easily serializable. In particular,
atlases that are loaded directly (e.g. sprite sheets) will not have a
copy of this map, and so, don't need to construct it at all.
As an aside, since this is the very first thing in `bevy_sprite` with
`serde` impls, I've added a `serialize` feature to the crate and made
sure it gets activated when the `serialize` feature is enabled on the
parent `bevy` crate.
## Testing
I was kind of shocked that there isn't anywhere in the code besides a
single example that actually used this functionality, so, it was
relatively straightforward to do.
In #13713, among other places, folks have mentioned adding custom
serialization into their pipelines. It would be nice to hear from people
whether this change matches what they're doing in their code, and if
it's relatively seamless to adapt to. I suspect that the answer is yes,
but, that's mainly the only other kind of testing that can be added.
## Migration Guide
`TextureAtlasBuilder` no longer stores a mapping back to the original
images in `TextureAtlasLayout`; that functionality has been added to a
new struct, `TextureAtlasSources`, instead. This also means that the
signature for `TextureAtlasBuilder::finish` has changed, meaning that
calls of the form:
```rust
let (atlas_layout, image) = builder.build()?;
```
Will now change to the form:
```rust
let (atlas_layout, atlas_sources, image) = builder.build()?;
```
And instead of performing a reverse-lookup from the layout, like so:
```rust
let atlas_layout_handle = texture_atlases.add(atlas_layout.clone());
let index = atlas_layout.get_texture_index(&my_handle);
let handle = TextureAtlas {
layout: atlas_layout_handle,
index,
};
```
You can perform the lookup from the sources instead:
```rust
let atlas_layout = texture_atlases.add(atlas_layout);
let index = atlas_sources.get_texture_index(&my_handle);
let handle = TextureAtlas {
layout: atlas_layout,
index,
};
```
Additionally, `TextureAtlasSources` also has a convenience method,
`handle`, which directly combines the index and an existing
`TextureAtlasLayout` handle into a new `TextureAtlas`:
```rust
let atlas_layout = texture_atlases.add(atlas_layout);
let handle = atlas_sources.handle(atlas_layout, &my_handle);
```
## Extra notes
In the future, it might make sense to combine the three types returned
by `TextureAtlasBuilder` into their own struct, just so that people
don't need to assign variable names to all three parts. In particular,
when creating a version that can be loaded directly (like #11873), we
could probably use this new type.